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Transcript
Cloningandfunctionalcharacterizationof
temperatureresponsivegenesinRicinus
communisL.
MarieChantalMutimawurugo
WageningenUniversity
September2014
WageningenSeedLab
LaboratoryofPlantPhysiology
WageningenUniversity
Cloningandfunctionalcharacterizationoftemperature
responsivegenesinRicinuscommunisL.
MarieChantalMutimawurugo
MScStudentPlantSciences
Registrationnumber
:761012592080
Code :PPH‐80439
Supervisor :PauloRobertoRibeirodeJesus
Examiners :Dr.Ir.WilcoLigterink(WUR)
Dr.HenkHilhorst(WUR)
Wageningen,September2014.
Abstract
Background: Ricinus communis L. (Castor bean) is an oilseed crop widely grown for vegetable oil and
renewablebio‐productsforpharmaceuticalandindustrialpurposes.However,castoroilproductiondoes
notmeettheincreaseofitsworldconsumptionduetotheuseofcultivarswithlowgeneticpotentialto
adapttosomeenvironmentalconditionslikeharshtemperatures.Castorbeanutilisesstorageoilforseed
germination and breakdown of this reserve is the main source of energy that is required for successful
seedling establishment before the plants become autotrophic. Temperature greatly affects germination
andseedlingperformance.However,themechanismsbehindtheeffectoftemperatureonthephysiology,
biochemicalandmolecularaspectsarenotfullyunderstood.Objectives:Toassesstemperatureeffecton
germination and post‐germination growth and to clone and characterize the function of three
temperature responsive genes: glycerol kinase (GK), malate synthase (MLS) and phosphoenolpyruvate
carboxykinase(PCK).MaterialsandMethods:Castorseedswereallowedtoimbibeandtogerminateat
20,25and35°C.Seedgerminationandseedlinggrowthwerefollowedfortwoweeks.Then,thenumberof
healthyseedlingsateachtemperaturewasrecorded.Cotyledonsandrootsofthehealthyseedlingswere
used to extract RNA. cDNA was synthesized from the isolated RNA, which was used during further
experiments.Genecloningwasperformedthroughgatewaytechnology.Forfunctionalcharacterizationof
theclonedgenesweusedtheNicotianabenthaminatransientexpressionsystemandtransformedleaves
were used for metabolite profiling experiments. Results: Germination percentage increased with the
increasing temperature while seedling performance decreased with the increasing temperature. Thus,
seedincubationat20°Cledtolowerpercentageofgerminatedseedwhileboth25and35°Carereported
tobetheoptimumtemperatureforoptimumgerminationrateincastorbean.Moreover,seedgermination
at 20°C resulted to high numberofseedling survivalfollowed by 25°C while at35 °C all seedlings died.
TransientexpressionofR.communisGK,MLSandPCKgenesinN.benthamianaleavesledtothereduction
of glucose levels with subsequently accumulation of starch. Discussion: Castor bean germination and
seedling performance are strongly affected by the temperature. In fact, the increasing temperature
resulted to high percentage of germinated but also to low seedling survival. This is due to the fact that
hightemperatureresultstorapidwateruptakerequiredforgerminationbutalsoleadstolowexpression
of genes that encode the enzymes GK, MLS and PCK which are involved in lipid breakdown to provide
energy for seedling growth. Conclusion: High temperature during germination led to low seedling
performanceduetolowexpressionofgenesthatencodeGK,MLSandPCKenzymes.Areductioninglucose
levelswhichwasfollowedbyanincreaseinstarchcontentinleavesthatwereinfiltratedwithMLSandGK
genes indicates that these genes are required for R. communis growth at the early of seedling
establishment.
Keywords:Castorbean,seedgermination,seedlingestablishment,lipidmobilization.
i
Abbreviations
AGS:
Amylo‐glucosidase
BLAST:
Basiclocalalignmentsearchtool
cDNA: complementaryDeoxyribonucleicacid
CHCl3:
Chloroform(synonym:MethylidynetrichlorideorTrichloromethane)
DMSO: Dimethysulfoxide
DTT: DL‐dithiolthreitol
EGTA: Ethyleneglycerol‐bis–tetraaceticacid
GC‐MS:
Gaschromatography‐massspectrophotometry
GKorGLI:
Glycerolkinase
G3P:
Glycerol‐3‐phosphate
HCl:
Hydrochloricacid
HPLC: Highperformanceliquidchromatography
ICL:
Isocitratelyase
KOH: Potassiumhydroxide
LB:
Lysogenybroth
MLS: Malatesynthase
MeOH: Methanolanhydrous
MES: 2‐(N‐morpholino)ethanesulfonicacid
Na‐DOC:
Sodiumdeoxycholate
NaOH: Sodiumhydroxide
NCBI: Nationalcenterforbiotechnologyinformation
OD:
Opticaldensity
PCK:
Phosphoeonylpyruvatecorboxykinase
i
PCR:
Polymerasechainreaction
PVP:
Polyvinlypyrrolidone
SDS:
Sodiumdodecylsulfate
TAG: Triacylglycerol
ii
TableofContents
Abstract...................................................................................................................................................................................i
Abbreviations.......................................................................................................................................................................i
1.Introduction.....................................................................................................................................................................1
1.1.Castorbeanproductionandusages...............................................................................................................1
1.2.Storagematerialmobilizationandseedlingestablishment.................................................................3
1.2.1.TAGlipolysis.....................................................................................................................................................4
1.2.2.β‐oxidation........................................................................................................................................................5
1.2.3.Glyoxylatecycleandgluconeogenesis...................................................................................................6
1.3.Transitionfromgerminationtoseedlingestablishment.......................................................................7
2.Materialsandmethods.............................................................................................................................................10
2.1.Germinationandpost‐germinativebehaviouranalysis.....................................................................10
2.2.RNAextractionandDNAsetreatment.......................................................................................................10
2.3.cDNAsynthesis....................................................................................................................................................11
2.4.Primerdesign.......................................................................................................................................................12
2.5.Geneamplificationandpurification............................................................................................................13
2.6.Genecloning..........................................................................................................................................................14
2.6.1.CloningofattBproductsviaBPreaction...........................................................................................16
2.6.2.GenesequencingandLRreaction.........................................................................................................17
2.6.3.Plasmiddigestionwithrestrictionenzyme......................................................................................17
2.6.4.GenetransferintoAgrobacteriumtumefaciens...............................................................................18
i
2.7.Transientexpression.........................................................................................................................................18
2.7.1.Bacteriaharvesting.....................................................................................................................................18
2.7.2.Agro‐infiltrationinNicotianabenthamiana.....................................................................................19
2.7.3.Metaboliteextraction.................................................................................................................................19
3.Results.............................................................................................................................................................................21
3.1.Seedgerminationandseedlingperformance.........................................................................................21
3.2.RNAextraction.....................................................................................................................................................23
3.3.cDNAsynthesis,geneamplificationandpurification..........................................................................24
3.3.1.Geneamplificationandtestofprimerperformance.....................................................................24
3.3.2.DNAfragmentsisolationandgenepurification..............................................................................26
3.4.Genecloning..............................................................................................................................................................26
3.4.1.BPreactionandgenetransfertoE.colicompetentcells............................................................26
3.4.2.GenesequencingandLRreaction.........................................................................................................28
3.4.3.PlasmiddigestionwithrestrictionenzymeandA.tumefacienscolony‐PCR......................29
3.5.MetaboliteprofilingintransgenicNicotianabenthamiana...............................................................31
4.Discussion......................................................................................................................................................................33
4.1.Seedgermination................................................................................................................................................33
4.2.Roleofstudiedgenesinseedlingperformance......................................................................................34
4.3.Genecloningandsequencing.........................................................................................................................37
4.4.MetaboliteprofileintransgenicNicothianabenthamiana................................................................37
Conclusion..........................................................................................................................................................................39
ii
Acknowledgements........................................................................................................................................................40
References..........................................................................................................................................................................41
Appendices........................................................................................................................................................................47
iii
1.Introduction
1.1.Castorbeanproductionandusages
Castor bean (Ricinus communis L) belongs to Euphorbiaceae family. Castor bean is a perennial
plant and it originates from Eastern Africa probably in Ethiopia. Castor bean is a plant which
preferssemi‐tropicalandtropicalconditionsforgerminationandgrowth.Itcangrowbetween
300‐1500maltitudeandoccasionallyupto3000m(Miller,2008).Castorbeangrowsinalmost
any soil, with the exception of very heavy clay and poorly drained soils. It can be grown in
unsuitable soil which is less fertile and therefore less suitable for food crops and this is a
considerableadvantageinlanduseefficiency.However,thehighestcastorbeanyieldisobtained
whenitisgrowninfertileandappropriatesoil.Forinstance,itwasreportedthatforgettinga
total yield of 1700kg/ha, plant takes up 50kg N,20kg P and 16kg K. In addition, theplant can
tolerate salinity up to 7.1 dS m‐1 beyond which seed germination can be affected with losses
above75%(SeverinoandDick,2013).
For optimum germination, a seed must be viable and contain enough reserve material (Miller,
2008).Moreover,theoptimumenvironmentalconditionslikewatertoactivateenzymesduring
germination and breakdown of storage material, temperature and air (especially O2) are also
required. Cheema and colleagues (2010) concluded that moisture availability and optimum
temperature are important factors which affect seed germination. Soil moisture content of 15‐
20% normally enables good germination at the optimum temperature (Weiss, 2000). As
mentioned above, oxygen is also required and 19% O2 is the optimum for germination while
highCO2(above4%)isharmful(BewleyandBlack,1994).However,Miller(2008)reportedthat
CO2concentrationhigherthan0.03%preventscastorseedgermination.
Theenvironmentalconditionsalso affectplant growthanddevelopment andconsequentlythe
seed yield. For instance, the temperature regulates seed germination by determining the
capacity and rate of germination or by removing/ inducing seed dormancy depending on the
species (Bewley and Black, 1994). Severino and colleagues (2012) reported that temperature
affectsseedgerminationincastorbeanandtheyrevealedinoneexperimentthat14to15°Cis
the minimum temperatures for castor bean germination. Miller (2008) defined the optimum
temperatureastheonegivingthehighestpercentageofgerminationintheshortesttime.Thus,
from a study conducted by Moshkin (1986) (reviewed by Severino and Dick, 2013) for castor
bean germination, the optimum temperature was reported to be 31°C and the maximum was
36°C.However,inanotherexperimentMoshkin(1986)revealed25°Castheoptimum(reviewed
by Severino and Dick, 2013). Moreover, Cheema and colleagues (2010) also reported that
1
althoughseedscangerminateat10°C,thefastergerminationoccursat25°Ctemperature.Beside
seed germination, temperature also affects other developmental stages (Weiss, 2000). For
instance,castorbeanfloweringoccursbetween20‐26°C.Whenthetemperaturerisesto40°Cat
flowering stage, flower basting occurs and there is a poor seed set. Moreover, too low or high
temperatures adversely affect castor seed composition. It was reported that below 15°C or
above35°C,oilandproteincontentofcastorseedarereduced.Atemperatureof‐2°Cfor4hours
usuallykillstheplantatanygrowthstage(Weiss,2000).
R. communis is widely grown for different usages. The most important is its production for
pharmaceuticalpurposesforhumanandveterinarymedicines(productionofhydroxylatedfatty
acids such as ricinoleic acid) (Kakakhel, 2008), petro‐chemicals and other industrial purposes
(oil for lubrication of different equipments, biodiesel production, source of renewable
polyurethanes,cosmetics,soap,paints)(Severinoetal,2012;Kakakhel,2008).Thisalsoreveals
the role of castor oil in environmental protection by using vegetable oils for biofuel and
renewablebio‐products(Severinoetal,2012).Moreover,castorbeancontainsothercompounds
such as allergens, the protein ’ricin’ and the alkaloid ’ricinine’ which are used for different
purposes.Allergenextractsareusedininsectpestmanagementinagriculturebecausetheyhave
aninhibitoryeffectonα‐amylaseactivitythatpreventsthehydrolysisofstarchintosugarsinthe
metabolism of insects. Ricinine at high quantity can also be used as organic insecticide while
ricinhasanegativeeffectonplantparasiticnematodesbyreducingtheiregglayingrate.
AcombinationofnematicideandcastormealreducesthegrowthofnematodeslikePratylenchus
sp.(Severino et al, 2012). In addition, incorporation of castor vegetative tissue into soil reduce
thegrowthandreproductionofMeloidogyneincognitaintomatoandlentilcultivationandcastor
bean leaf extract kills M. exigua juveniles in coffee. In agriculture, castor bean is also used as
organicfertilizerbecausethehuskby‐producthashighKcontent(Kakakhel,2008).Castorby‐
productsalsocanbeusedinanimalfeedapplicationassourceofproteinafterremovaloftoxic
compounds like ricinine and ricin (Severino et al, 2012). Castor bean also is used as an
ornamentalplantduetoitsattractivecoloursofleavesandinflorescences(Kakakhel,2008).
Besidethementionedroles,castorbeaniscultivatedbecauseofitshighabilitytotoleratesaline
and drought conditions (Graham, 2008). These aspects play an important role in land use
systemsasmostofthefarmerstendtogrowfoodcropsingoodsoilandothercropsintherest.
Drought tolerance in castor bean is mainly due to its large and well‐developed tap‐roots with
considerable lateral roots both enabling a deep penetration and high soil exploration to take
maximumsoilmoisture(Weiss,2000).
2
Anotherreasonofthispotentialindroughttolerancecouldbeduetoitshighstomatalcontrol
enabling plants to minimize the transpiration rate by keeping also a high level of net CO2
assimilation under water stress conditions (Severino et al., 2012). These physiological traits
enablecastorbeantousethesoilmoisturemoreefficientlythanmostfoodcrops(Weiss,2000).
Another important role of castor plant is its use for phytoremediation of soils containing high
levels of heavy metals such as Pb, Zn, Cd and Ni. This plant is tolerant to those metals and
accumulatestheminitstissues.Thus,itcanmakesoilsmoreproductiveforfoodcrops(Romeiro
etal.,2006;Liuetal.,2008citedbySeverinoetal.,2012).Anadditionaladvantageofgrowing
castorplantinarotationplanisthatitinducesthegerminationofStrigaspp,aparasiticplantof
cereals crops especially in Africa, to which itself is resistant. Therefore, crops following castor
beanbenefitfromlowerStrigainfestation(Weiss,2000).
However, castor bean production (around 0.15% of vegetable oil produced in the world) and
supplydonotmeettheworlddemandwithademandincreaseof50%duringthepast25years
(Severinoetal.,2012)especiallyindevelopedcountrieswheretheyprefertheusageofnatural
oils(Weiss,2000).ThisisduetothefactthatonlyafewcountriesintheworldsuchasBrazil,
India, China, Russia, Thailand and Mozambique produce a considerable amount of castor bean
(Severino and Dick, 2013; Kakakhel, 2008) and the seed oil content also varies for different
growinglocations(Severinoetal.,2012).Moreover,otherconstraintsincastorbeanproduction
areduetothelowtechnologyinproductionandtheuseofvarietieswithlowgeneticpotential.
Therefore, breeding for cultivars that combine the potential of high yield and adaptation to
differentenvironmentalconditionsbytoleratingtemperature,salt,anddroughtwouldbeagood
way of increasing overall castor bean production (Weiss, 2000). This requires a good
understandingoftheinteractionbetweengenetictraits,theenvironmentandcropmanagement
(SeverinoandDick,2013).
1.2.Storagematerialmobilizationandseedlingestablishment
Generally,therearethreemajorfoodreservesinplants:fatsoroils,carbohydrates,andproteins.
Fatsarethemostefficientformforenergystorageastheycontainmorethantwicetheenergy
storedinotherreservesmentionedabove(QuettierandEastmond,2009;Huang,1992).Bewley
and Black (1994) reported different reserves in castor bean endosperm which is mainly
composed of oil (64%), protein (18%) and negligible carbohydrate. Moreover, Weiss (2000)
reported that castor seed is mainly composed of oil (40‐60% depending on cultivar and
environment),triglycerides(ricinolein)andfattyacid(ricinoleicacid).Castorbean,likeotheroil
crops, accumulates oil reserves in the seeds during seed filling and maturation. In castor bean
3
seeds, the oil reserves are stored in the form of triacylglycerol (TAG) compounds (Baud and
Lepiniec, 2010) which consist of esters of glycerol and fatty acids (Quettier and Eastmond,
2009). These compounds are accumulated within specialised structures called oil bodies
localized in cytosol (Theodoulou and Eastmond, 2012). These TAGs serve as reserve for seed
germination and its mobilization is essential as source of carbon for successful seedling
establishment(Graham,2008).Thetransitionfromseedtoseedlingisacriticalstepinthelife
cycle of plants and in oilseed crops it is determined principally by the breakdown of TAG
reserves(QuettierandEastmond,2009;EastmondandGraham,2001).
The breakdown of TAG reserves into carbohydrates can start before the germination is
completed and continues during post‐germinative growth with the major mobilization in the
growing organs after radicle elongation (Graham, 2008; Bewley and Black, 1994). It is
mentionedabovethattheoilreserveisrequiredduringseedgermination,butitsmobilizationis
onlyneededforseedlingestablishment;astageinwhichseedlingsrequirethecarbohydratesfor
energetic resource for rapid growth and development before they become autotrophic
organismsviaphotosynthesis(Kellyetal.,2011).Therefore,thehighertheoilreservesandits
solubility, the better seedling establishment and vigour of seedlings for ultimate crop
establishmentandhighseedyield(KornbergandBeevers,1957;Graham,2008).
In castor bean like in other oil crops, lipid reserves undergo a complex pathway for the
conversion to carbohydrates required for seedling development and supporting
photoautotrophic metabolism. This mechanism involves a metabolic pathway which occurs
through the following pathways: TAG lipolysis, β‐oxidation, glyoxylate cycle and
gluconeogenesis. The main enzymes involved in this long pathway are lipase in TAG lipolysis,
glycerolkinase(GK)in thedirectconversion ofglycerolinto glycerol‐3‐phosphate(G3P),acyl‐
CoA synthetases (LACS), acyl‐CoA oxidase (ACX), multifunctional proteins (MFPs) and 3‐
ketoacyl‐CoAthiolase(KAT)inβ‐oxidation,isocitratelyase(ICL)andmalatesynthase(MLS)in
glyoxylate cycle and finally phosphoenolpyruvate carboxykinase (PCK) in gluconeogenesis
(BaudandLepiniec,2010;Graham,2008).
1.2.1.TAGlipolysis
The first step of oil breakdown in oilseed crops is TAG lipolysis, a pathway by which lipase
enzymes hydrolyse TAGs stored in cytosolic oil bodies into glycerol and free fatty acids (FA)
(Penfield et al., 2005, Karim et al., 2005). TAG lipase is encoded by sugar dependent 1 (SDP1)
locus(Graham,2008;Eastmond,2006)(Figure1).
4
Figure1.Storageoilbreakdown.Yellowcolorindicatesoilbodyandcytosolicpathwaylocation,greenindicatespathway
involvedindirectglyoxysomalβ‐oxidation,grey(glyoxylatecycle),andblue(gluconeogenesis).Graham(2008).Annual
review.PlantBiology,59:115‐142.
TAG lipolysis produces FAs and glycerol in a 3:1 ratio in which glycerol represents
approximately 5% of the total carbon produced. Glycerol is phosphorylated by glycerol kinase
(GK) to produce glycerol‐3‐phosphate (G3P) and the later enters gluconeogenesis to yield
carbohydrates (hexose for cell wall synthesis or sucrose for seedling development) (Graham,
2008)(Figure1)orbeusedasarespiratorysubstrateafteritsconversiontodihydroxyacetone
phosphate by glycerol‐3‐phosphate dehydrogenase (Quettier and Eastmond, 2009; Penfield et
al., 2005). Although glycerol represents a small carbon reserve its contribution to seedling
growth is significant and essential especially in the absence of a functional glyoxylate cycle
where it can compensate for the lack of carbons released from this pathway (Penfield et al.,
2005).
1.2.2.β‐oxidation
β‐oxidation in oilseeds occurs within glyoxysomes (Borek et al., 2013). Therefore, fatty acids
must be transferred from the oil body to this cell compartment (Theodoulou and Eastmond,
2012) by Transporters such as COMATOSE (CTS) ATP‐binding cassette (ABC) (Graham, 2008;
Penfield et al., 2005). This pathway results in the production of molecules of two carbon unit
(C2) Acetyl‐CoA from FA oxidation and additionally hydrogen peroxide (H2O2) (Borek et al.,
2013;Graham,2008;BewleyandBlack,1994).Thelaterisultimatelydestroyedbyperoxisomal
5
catalases(Penfieldetal.,2005).FAsarefirstesterifiedintoacyl‐CoAsbytwolongchainacyl‐CoA
synthetases (LACS 6 and 7) before entering the β‐oxidation pathway (Theodoulou and
Eastmond,2012;GramandGram,2005).Theseacyl‐CoAsareusedasstartingmaterialsofthis
pathway(BewleyandBlack,1994)andmanyenzymesandmultifunctionalproteins(MFPs)are
requiredforitsoxidation,hydration,dehydrogenationandcleavage(Figure1)(Theodoulouand
Eastmond, 2012; Graham, 2008). The initial oxidation of acyl‐CoAs is catalyzed by acyl‐CoA
oxidase(ACX)andthenextstepsarecatalyzedbyMFPandthe3‐ketoacyl‐CoAthiolase(KAT)
(Graham,2008).
TheproducedAcetyl‐CoAcanundergotwodifferentpathways.Itcaneitherentertheglyoxylate
cycle for carbohydrate synthesis or it can be completely converted into citrate to be used for
respiration via citric acid cycle (Penfield et al., 2005; Bewley and Black, 1994). The level to
which Acetyl‐CoA is converted to either carbohydrate or citrate depends on plant physiology.
For instance in the case of castor bean, the oil molecules are mainly stored in the seed
endosperm and the latter is completely degraded during germination. The demand of Acetyl‐
CoA for respiration in this tissue is negligible. Thus, the most part of products from oil
breakdown are converted to carbohydrate required for seedling growth instead of the
respiratory pathway. However, in other oilseed crops like Arabidopsis and sunflower, the oil
reservesaremainlyaccumulatedinthecotyledons.Thelatterpersistafteroildegradationand
become photosynthetic active tissue. Thus, in these plants there is a high demand of organic
compoundsfromFAdegradationforrespirationcomparingtothemoleculestransportedincells
for carbohydrate biosynthesis. In oilseed plants, FA β‐oxidation continues until the complete
degradationoffattyacids(GrahamandEastmond,2002).
1.2.3.Glyoxylatecycleandgluconeogenesis
TheglyoxylatecycleisacentralandcrucialpathwayinTAGconversiontocarbohydrateduring
seedling establishment in oilseed crops (Nakazawa et al., 2005; Runquist and Kruger, 1999).
This occurs in both the glyxosomes and the cytosol (Graham, 2008) (Figure 1). The glyoxylate
cycleconvertstheAcetyl‐CoAsproducedfromβ–oxidationintoorganicacidswithfour‐carbon
unitssuchasmalate(Graham,2008;Nakazawaetal.,2005).Thispathwayisperformedbyfive
keyenzymes(Boreketal.,2013;Graham,2008).Twoofthem,isocitratelyase(ICL)andmalate
synthase(MLS),areconsideredasuniqueenzymesoftheglyoxylatecycle.MLSdirectlyconverts
Acetyl‐CoA into malate while ICL catalyzes the conversion of isocitrate into glyoxylate or
succinate. Glyoxylate is subsequently also converted into malate by MLS (Graham, 2008;
Nakazawaetal.,2005).
6
The other three enzymes, malate dehydrogenase (MDH), citrate synthase (CSY) and aconitase
(ACO)functionbothintheglyoxyalatecycleandthetricarboxylicacid(TCA)cycle(Boreketal.,
2013;Graham,2008).Malateisusedassubstrateforoxaloacetate(OAA)productionbycytosolic
MDH(QuettierandEastmond,2009;Graham,2008;Penfieldetal.,2005).OAAinturncaneither
enter gluconeogenesis or be converted into citrate by citrate synthase (CSY) and then
transported to the mitochondria for respiration (Borek et al., 2013). The glyoxylate cycle
dependsonsubstratesderivedfromFAoxidationandthesearesubsequentlyconvertedeither
into succinate or citrate by the TCA cycle or into phosphoenolpyruvate (PEP) by
gluconeogenesis (Theodoulou and Eastmond, 2012). Usually, the TCA cycle for respiration is
suppressed in favour of carbohydrate biosynthesis when the glyoxylate cycle is active in
germinating seeds. During storage lipid breakdown, the seedling must adapt to the
environmental conditions especially during the glyoxylate cycle to complete this mobilization
efficientlyandtoreachthephotoautrophicphasebeforetheexhaustionofreserves(Eastmond
andGraham,2002).
Thegluconeogenesispathwayoccursinthecytosolanditsstartingstepischaracterizedbythe
conversion of oxaloacetate into phosphoenolpyruvate (PEP) by phosphoenolpyruvate
carboxykinase(PCK),akeygluconeogenesisenzyme (Rylottetal.,2003).PEPisthenconverted
intoG3Pwhichcanbeconvertedintosolublecarbohydrateslikehexosewhichcanbeusedfor
cell wall synthesis or sucrose for the support of seedling development (Borek et al., 2013;
Graham,2008;KornbergandBeevers,1957)(Figure1).
1.3.Transitionfromgerminationtoseedlingestablishment
As mentioned before, the transition from seed germination to seedling establishment is the
crucial stage in the plant life cycle and its success in oilseed plants depends on the lipid
mobilization which is performed by many enzymes and associated proteins (Graham, 2008).
Theseenzymesandproteinsrequireoptimumenvironmentalconditionsfortheirstructureand
functional stability. Beside pH, the other most important factor affecting this stability is
temperature. It is known that below the optimum temperature, the increase of temperature is
associated with an increase of the functional rate of enzymes, while above this temperature
there is enzyme denaturation accompanied with a decrease in reaction rate (Granjeiro et al.,
2004). Temperature also affects seed germination and plant physiology in a species specific
manner(BewleyandBlack,1994).Inthislightitisclearwhythereisanoptimumtemperature
foroptimalseedlingestablishmentinrespecttoenzymaticactivityduringseedgerminationand
storageoilcatabolism.
7
A previous study conducted at different temperatures (20, 25, 35°C) revealed that seed
germinationincastorbeanwasfasterathighertemperature.However,seedlingestablishment
wasnegativelyaffectedbyharshtemperature(personalcommunicationPaulo,2014)(Figure2).
Figure 2. Effect of temperature on seed germination (percentage and speed) (A and B) and seedling health (C) in R.
communis. Error bars were put though the averages of treatments and different letters indicate significant difference
betweenmeansoftreatments.
Besideseedgerminationandseedlinghealth,differenttemperatureswerealsoreportedtoaffect
theexpressionofgeneswhichencodeenzymesinvolvedinstorageoilmobilizationtoensurethe
successofcastorbeanseedlingdevelopment.AlthoughtheexpressionofgenesencodingforICL,
MFP,LACS6/7andKATenzymeswereconsiderablysimilaratdifferenttemperaturesduringthe
post‐germinative stage, other enzymes like ACX, GLI1 or GK1, MLS and PCK were lower
expressedat35°C(Figure3)(PersonalcommunicationPaulo,2014).
Figure3.EffectoftemperatureongeneexpressionduringthegermintaionandpostgerminativephaseinR.Communis.
Error bars were put through the averages of treatments and different letters indicate significant difference between
means.
8
It is reported that all these enzymes are highly regulated at both transcriptional and
posttranscriptionallevel(Graham,2008).Somefactorsbehindthisregulationareknownwhile
othersarenotwellunderstood.Itisalsoreportedthatthereisaninteractionbetweenspecific
transcription factors and the physiological signals (Baud and Lepiniec, 2010). Penfield and
colleagues(2004)reportedthatadisruptionofgenesencodingGK,MLSandPCKresultedtolow
hypocotylelongation.Althoughallthesegeneswereshowntoaffectseedlingperformance,none
of the studies describe the effect of temperature on expression level of these genes during
germinationandhowtheycouldaffectseedlingperformance.
Therefore,theaimofthisstudyistocloneandcharacterizethefunctionofgenesencodingGK,
MLSandPCKenzymes.Thestudywillfocusonthesethreegenesthatareconsideredtobethe
mainenzymesinvolvedinthestorageoilbreakdownespeciallyduringtheglyoxylatecycleand
gluconeogenesis and that are also affected by different temperatures. Therefore, their
expressionandfunctionareexpectedtohavehigherimpactonseedlingestablishmentandpost‐
germinative stages of castor bean. The goals of this project will be achieved by assessing the
germinativeandpost‐germinativebehaviourofcastorbean,cloningofthegenescodingforGK,
MLS and PCK in R. communis and their functional characterization in transgenic Nicotiana
benthamianaplants.
Thisexperimentwillcontributetoanunderstandingofthemechanismbehindtheexpressionof
theseenzymesatdifferenttemperaturesandtheirfunction.Thefinaloutcomewillbeusefulfor
theimprovementofcastorbeancultivarsthatcansurvivethecrucialgrowthstageofseedling
establishmentunderharshenvironmentalconditionsatdifferentlocationsintheworld.Ahigh
post‐germinativegrowthleadstoabetterplantdevelopmentinthelaterstagesandultimately
to a higher seed yield. The adaptation potential to different environments will also enable
extensionofgrowingareasandincreasingyields.Alltheseaspectswillcontributetoahighseed
productiontomeettheworlddemand.
9
2.Materialsandmethods
2.1.Germinationandpost‐germinativebehaviouranalysis
ThisstudywasconductedintheWageningenSeedLabfromthelabofPlantPhysiologyatRadix
(WageningenUniversity)fromFebruaryuntilAugust2014.SeedsofR.CommunisL.cvMPA11
were surface sterilized by dipping them in a solution of bleach and demi water (1:4 ratio).
Subsequently, the seeds were germinated in trays containing white blotter filter‐paper with
additionof30mlofdemi‐waterandcoveredwithanextrafilter‐paperonwhich20mlofwater
wasadded.Seedswereincubatedatthreedifferenttemperatures(20,25and35°C)inthedark.
Foreverytemperature,fourreplicatesoffifteenseedseachwereused.Wateringandcountingof
germinated seeds was done twice a day for two weeks. The number of healthy seedlings was
countedoneandtwoweeksafterthebeginningofimbibition.Aftertwoweekscotyledonsand
rootsfromthehealthyseedlingswerecollectedandkeptat‐80°Cpriortofurtheranalysis.The
analysisofdatafromseedgerminationandseedlinghealthexperimentswasperformedbyexcel
and GenStat softwares for Analysis of Variance (ANOVA) and Student t‐test to determine the
differenceinparametersduetotreatmentsat5%levelofsignificance.
2.2.RNAextractionandDNAsetreatment
Plant materials were freeze‐dried for two days before RNA extraction. RNA extraction was
performed with the hot‐Borate protocol as described by Jawdat and Karajoli (2012). The hot‐
boratebufferwasmadewith50mlDEPCinwhichwereadded3.81gof0.2MNaborate,0.57gof
30mMEGTA,0.5gofSDSand0.5g ofNa‐DOC.Thisbufferwasusedtomaketheextraction(XT)
buffer by adding 264mg PVP and 8.8mg DTT to 4.4 ml of hot‐borate buffer. The buffer was
incubated at 80°C to enable complete dissolution. Ten milligrams of freeze‐dried and ground
rootsorcotyledonsweremixedwith800μlXT‐buffer.Then,afteradding4µLproteinaseK(ca.
0.3mg/μL),sampleswereincubatedat42°Cfor15minutes.Subsequently,64μlof2MKClwas
addedandsampleswereincubatedonicefor30minutesfollowedbyacentrifugationat12000g
at4°Cfor20minutes.700µLofsupernatantwastransferredtoanewtubeand259µLof8M
LiClwasaddedandincubatedovernightonice.
Subsequently, samples were centrifuged at 12000g at 4°C for 20 minutes and the remaining
pelletwaswashedwith750µLof2MLiCl.Thepelletwasresuspendedin100µLDEPC‐treated
water.InordertoremovegenomicDNA,10μgofRNAwassubjectedtoaDNAsetreatmentby
adding10µLofDNAsebufferand10µLofDNAseenzyme(Table1).
10
Table1.Calculatedvolume(µL)ofRNAbasedonconcentration(ng/µL)andmass(10µg).
Treatment
(°C)
Plantmaterials
20
Roots
Cotyledons
Roots
Cotyledons
25
RNA
concentration
(ng/µL)
272.9
229.1
191.7
147.9
RNA mass RNAvolume(µL)
(µg)
10
10
10
10
36.64
43.65
52.16
67.61
Inthenextstep,sampleswereincubatedat37°Cfor20minutes.Then,weadded100µLphenol
chloroform and after a new centrifugation for 30 seconds. Approximately 90 µL of the upper
phasewastransferredtoanewEppendorftubeinwhich9µLof3MNaAcand225µLof100%
ice‐cold ethanol was added and RNA precipitated overnight at ‐20°C. The pellet was washed
with 250 µL cold 70% ethanol and subsequently dissolved in 20 µL DEPC‐treated MQ water.
RNA concentration and quality control were assessed by using Nanodrop spectrophotometer
andRNAintegritywascheckedbyagarosegelelectrophoresis.
2.3.cDNAsynthesis
cDNA synthesis was performed by using a cDNA synthesis kit (Biorad) for first‐strand cDNA
synthesis. It contained the RNase H+ iScript reverse transcriptase for sensitivity, a premixed
RNaseinhibitortopreventindiscriminatedegradationofRNAtemplate.First,areactionsolution
waspreparedbymixing4µL5xiScriptreactionmix(buffer),1µLiScriptReverseTranscriptase
enzyme,RNAtemplatevolumecalculatedfromtheRNAconcentrationsobtainedonNanoDrop
inordertouse1µgRNAandnucleasefreewater(DEPC)togetatotalvolumeof20µL(Table2).
Table2.CompositionofsolutionforcDNAsynthesis
Treatment
(°C)
Plant
materials
RNAmass RNA
(µg)
concentration
(ng/µL)
RNA
Nuclease
template
free water
volume
(µL)
(µL)*
20
Roots
1
417.7
2.4
12.6
Cotyledons 1
186.3
5.4
9.6
25
Roots
1
184.2
5.4
9.6
Cotyledons 1
400.4
2.5
12.5
* Equation for calculating RNA template volume: V=M /C ; where V: Volume (µL), M: Mass (µg) and C:
concentration(ng/µL)
11
Reverse transcription was performed at 37°C for 40min followedby 85°C for 5min. The cDNA
was diluted 40 times and stored at ‐20°C prior to the analysis. RcNIC1 primer was used as
controltocheckthesynthesisofcDNA(Table3).
Table 3. Sequence of R. Communis nicotinamidase1 (RcNIC1), a primer used for cDNA
amplification
Genename
Primer
number
GI:255586656|
1529
|ref|
AT2G22570.1|
1530
Ricinus
communis
nicotinamidase1
Primername
RcNIC1_cloningF
Annealing
temperature
(°C)
59
RcNIC1_cloningR
59
Primersequence
ATG GTC TCC TCC ACG
GTTGAATTG
CTA TTG CAG TGC ACT
AACAGACACCTC
FulllengthofcodingregionofNIC1=732bp
2.4.Primerdesign
Theidentificationofcandidategenesrelatedtoglycerolkinase(GK),malatesynthase(MLS)and
phosphoenolpyruvate carboxykinase (PCK) in R. communis and their DNA sequences was
performed through NCBI software in which BLAST program was used to get candidate genes
from those of Arabidopsis thaliana species. On the basis of the DNA sequences, forward and
reverseprimerswithoutandwithattBsitesweredesigned(Table4).Primeramplificationwas
assessed at different temperatures by a Bio‐Rad thermal cycler machine and agarose gel
electrophoresis.
12
Table4.PrimersequencewithoutattBsitesfornormalPCR.
Genename
Basepair(bp)
Full
Coding
region
>gi|255553276|ref|
1566
XM_002517635.1|
Ricinus communis glycerol
kinase,
putative,mRNA
1566
Primer
number
Primer
name
Annealing
temperature
(°C)
Primer
sequence
2169
RcGLI
cloning_F
53.4‐53.5
ATG GCA AAA
CAGGAACCAG
2170
RcGLI
cloning_R
2171
RcMLS1
cloning_F
2172
RcMLS1
cloning_R
2173
RcMLS2
cloning_F
2174
RcMLS2
cloning_R
2175
RcPCK1
cloning_F
RcPCK1
cloning_R
>gi|255540320|ref|
1812
XM_002511179.1|
Ricinus communis malate
synthase,
putative,mRNA
>gi|21075|emb|X52
1826
806.1|
Ricinus
communis mRNA for malate synthase (EC
4.1.3.2)
2333
>gi|255537863|ref|
XM_002509951.1|
Ricinus communis
Phosphoenolpyruvat
e
carboxykinase
[ATP],
putative,
mRNA
>gi|255576016|ref|
2001
XM_002528858.1|
Ricinus communis
Phosphoenolpyruvat
e
carboxykinase
[ATP],
putative,
mRNA
1704
1704
1986
2176
2001
2177
RcPCK2
cloning_F
RcPCK2
cloning_R
2178
52.8‐52.0
53.7‐53.4
54.2‐52.2
TCA TAT TGA
AAG ATC AGC
CAAGC
ATG ATG CGA
TAT GAT ACT
TATGGTG
ACT TAT TCA
CAG CCT AGA
TGATC
TGA TGC GAT
ATG ATA CTT
ATGGTGA
GAA ATC AAC
ATT ATT CAC
AGCCTAGA
ATG GCG GAG
AATGGAGAG
58.2‐57.5
TCA AAA ACC
AAT CTG ATC
AGAGATA
ATG GCG ACC
AACGGCAAT
TTA GAA ATT
CGG ACC AGC
TGCC
ThesequencesofprimersattBsiteswhichwereusedforDNAamplificationwere5’‐GGGGACA
AGTTTGTACAAAAAAGCAGGCT‐3’forforwarddirectionand3’‐GGGGACCACTTTGTACAA
GAAAGCTGGGT‐5’forreversedirection.
2.5.Geneamplificationandpurification
Amplification of the full length coding region of the candidate genes was done with a total
volumeof15µLsolutionfornormalPCRreactionscomposedof1.5µL10xBufferB,1.5µLof
25mMMgCl2,6.65µLDEPC,0.15µLTagpolymeraseenzyme(firepol)(5U/µL),0.4µLof10mM
dNTPs,4.0µLcDNAand0.8µLofprimer(10µM).Inaddition,thePCRwasalsodonebyusing
phusionpolymerase(2U/µL)enzymeandprimerswithattBs.PCRwasfirstperformedbyfirepol
13
polymerase, an enzyme with high thermo‐stability and polymerization and then we used
phusionbecauseitisaHigh‐FidelityDNAPolymeraseswhichisusedtoknowifacorrectionis
needed in DNA sequence. During PCR amplification, DNA denaturation, primer annealing and
polymerase reaction were performed by different thermal conditions. The exposure of the
solution to high temperature (95°C) allowed DNA denaturation into single‐strands. When the
temperature was decreased to an annealing temperature according to the gene, the primer
annealed to specific nucleotides (their complementary sequences). Raising the temperature to
72°C enabled optimal functioning of the Tag polymerase or phusion polymerase by adding
nucleotides for synthesis of the second DNA strand. After PCR amplification, samples were
analysed by 1% agarose gel electrophoresis for cDNA fragment characterization and quality
control.
Gene purification was performed by a QIAquick Gel Extraction Kit method following the
manufacturer’sinstructions.First,amplifiedfragmentswithdesiredsizewerecutfromthegel
under UV light. Subsequently, an addition of 3 volumes of QIAquick Gel Extraction Kit buffer
(QG) to 1 volume of gel slice was followed by incubation at 50°C and regular mixing for a
complete dissolution. Subsequently, 500 µL of isopropanol was added and the solution was
appliedtotheQIAquickcolumnandcentrifugedfor1minute.Thecolumnwaswashedwith750
µL of buffer PE followed by centrifugation. Finally, the column was transferred to a new
microcentrifuge tube and 20 µL of MQ water was added to the centre of membrane and
centrifuged once to elute the plasmid. The concentration of purified fragment was measured
withaNanoDropspectrophotometer.
2.6.Genecloning
Gene cloning was performed by Gateway technology. The production of clones was performed
byenablingarapidandefficientrecombinationofDNAfragmentsoftargetgeneswiththedonor
and destnation vectors (pDONr207 and pGD625 respectively) through a site‐specific
recombinationproperty.Moreover,genecloningensuredatransferofrecombinantsDNAsinto
the host (E.coli) in which they replicated. With this technology four main steps were done:
cloningofattBproductsviaBPreaction,genesequencing,LRreactionandtransferoftargeted
genesintoAgrobacteriumtumefaciens(Agl0strain)(Figure4).
14
Kan.=Kanamycin;Rif.=Rifampicin
Figure4.DifferentstepsinGatewaycloningtechnology
15
2.6.1.CloningofattBproductsviaBPreaction
During the BP reaction, we mixed 1 µL of donor vector (pDONr 207) (100ng/µL), 2 µL of TE
buffer,1µLofattBsPCRproductand1µLofBPclonase.Thelatercatalyzedtherecombination
andinsertionofattBsofthePCRproduct(expressionclone)intoattPrecombinationsitesinthe
donorvectortomaketheentryclonewithattLsites.Thetotalvolumeof5µLwascentrifuged
for20secondsandincubatedat25°Covernight.Thisstepwasfollowedbyanadditionof1µLof
ProteinaseK(3‐15U/mg)andincubationat37°Cfor10minutes.
OncetheentryclonewasformeditwastransferredtoE.coli(DH5α)cellsviaelectroporation.
For this step, 1 µL of plasmid was mixed with electro competent E.coli cells followed by
transformation by electroporation at 2.5 voltages (2 mm cuvette). The transformed cells were
mixedwith400µLofLBliquidmediumandincubatedat37°Cfor1hourtoallowbacteriafrom
electroporation shock to recover. These cells were transferred to plates containing LB solid
medium and gentamicin (25 µg/mL). This antibiotic ensures the growth of only transformed
bacteria which contain plasmids able to resist to it. The next day, single colonies from each
plasmid were transferred to both LB liquid and solid media also containing gentamicin. The
mixtureswerethenincubatedat37°Covernight.
Beforeplasmidisolation,glycerolstockofeachgenewasmadebyadding750µLoftransformed
E.coli cells containing target gene to 250 µL of glycerol (60%) solution. Those glycerol stocks
were immediately transferred to liquid nitrogen and stored at ‐80°C for further usages. Then,
plasmid isolation was performed by QIAprep Spin Miniprep Kit High‐Yield method. 3.25 mL
mediumfromeachplasmidwascentrifugedat>8000rpmfor3minutesfollowedbyadditionof
250 µL of both Buffer P1 and Buffer P2 to the pellet and resuspension of the pellet by mixing
untilnoclumpsofcellsremained.
Afterincubationfor5minutesatroomtemperature,350µLofBufferN3wasaddedfollowedby
vortexing, centrifugation for 10 minutes and transfer of the supernatant to a QIAprep spin
column. After centrifugation the column was washed with 500 µL Buffer PB. Next, the column
was transferred to a new microcentrifuge tube and 40 µL of MQ‐water was added to its
membrane.Afterincubationfor1minute,thetubeswerecentrifugedfor1minutetocollectthe
plasmidandtheconcentrationwasmeasuredbyNanoDrop.
16
2.6.2.GenesequencingandLRreaction
After a normal PCR with isolated plasmids, positive plasmids were sequenced by mixing 5 µL
forwardorreverseprimer(10µM)forpDONR207with5µLofplasmiddilutedwithMQwater
regardingtheDNAconcentrationstoget100ngofDNA.SequencingwasperformedbyMacrogen
Europe and the results were compared with the sequences of the reference genes in the
databasewithCLCbio.PositiveplasmidsweresubjectedtoLRreaction.AnLRreactionwasused
in a similar way as the BP reaction to generate a destination vector containing the gene of
interestwiththedifferencethatwe usedLRclonaseinsteadofBPclonaseandthedestination
vectorpDG625withattRsitesinsteadofpDONR207withattPsites.Anotherdifferencewasthat
after transferring plasmids from LR reaction into E.coli through electroporation, the bacterial
cells were transferred to plate containing LB solid medium with kanamycin instead of
gentamicin.ThiswasalsofollowedbytransferoftransformedsinglecoloniesintoLBliquidwith
kanamycinandplasmidisolationasdescribedabove.
2.6.3.Plasmiddigestionwithrestrictionenzyme
In the next step, different isolated plasmids containing target genes were digested with
restrictionenzyme(Table5).RestrictionenzymeusedwasEcoRIwhiletheemptyvectorusedas
controlwaspDG625.Inprinciple,thiswasperformedbymixingXXXµLofMQ,500ngofDNA,1
µLofenzymeand2µLofBufferCutSmartinordertogettotalvolumeof20µL.Aftermixing,the
solution was kept at 37°C for 1 hour and heated at 65°C for 10 minutes. Plasmid fragments
(numberandsize)oftransformedcellsandemptyvectorwereconfirmedthrough1%agarose
gelelectrophoresis.
Table5.Volumeofdifferentcomponentsusedforgenedigestionwithrestrictionenzyme
Gene/vector
Clone
MLS1
MLS1‐3‐1
MLS1‐3‐2
MLS1‐3‐3
pDG625‐2
GK‐2‐5
GK‐3‐2
PCK1‐2‐1
PCK1‐2‐2
pDG625‐2
pDG625*
GK
PCK1
pDG625*
Concentration Volume MQ
(ng/µL)
of
(µL)
plasmid
(µL)
111.2
4.5
12.5
96.2
5.2
11.8
77.9
6.4
10.6
83.9
5
12
31.4
10
‐
21.0
10
‐
27.6
10
‐
27.5
10
‐
83.9
5
5
*:Plasmidwhichwasusedascontrolfordigestionwithrestrictionenzyme
17
Buffer Enzyme Total
(µL)
(EcoRI) volume
(µL)
(µL)
2
2
2
2
1.2
1.2
1.2
1.2
1.2
1
1
1
1
1
1
1
1
1
20
20
20
20
12.2
12.2
12.2
12.2
12.2
2.6.4.GenetransferintoAgrobacteriumtumefaciens
The last step of gene cloning concerned the transfer of plasmids from digestion into
Agrobacteriumtumefaciens(Agl0strain)viaelectroporation2.5V(2mmcuvette)aftermixing1
µL of plasmid with Agl0 competent cells. Then, the bacteria were kept at 28°C for 1 hour for
recovery followed by transfer to plate with LB solid medium, kanamycin (100 µg/mL) and
rifampicin (25 µg/mL) and incubation at the same temperature for 2 days. After colony‐PCR
which was done to confirm the presence of desired genes into Agrobacterium cells, positive
bacterial colonies were transferred to LB liquid medium containing the same antibiotics and
grownat28°Cfor2daysforfurtherusagesinplanttransformation.
2.7.Transientexpression
2.7.1.Bacteriaharvesting
To characterize the function of the cloned genes, transient expression was performed in N.
benthamiana leaves with the help of Agrobacterium tumefaciens. The bacteria containing the
plasmids with targeted genes (Agl0‐GK, Agl0‐MLS and Agl0‐PCK ), Agl0‐EV (empty vector
ImpactTim1.1)andAgl0‐P19wereharvestedfromLBliquidmediumbycentrifugationat5000g
at20°Cfor15minutesandAgro‐infiltrationbufferwasaddedtoeachtoobtainanOD600of0.5.
This buffer was previously prepared by mixing 952.11mg MgCl2 (500mM), 2132 mg of MES
(500mM)and1LofdistilledwaterandadjustedtoapHof5.7with1NKOHbeforeadding1mL
Acetosyringone(100mM).
Afterthat,4mLofP19wasmixedwith4mlofGK,MLSandPCKplasmidswhile8mLwasused
for empty vector. P19 is a plasmid of Cymbidium ringspot virus (CymRSV) which contains
doubles‐strandedsiRNAs(smallRNAs).Theaccumulationof doubles‐strandedsiRNAsinplant
resultstoRNAsilencingininfectedplantandsubsequentlytorepressionofdefencesignalling.
P19 was reported to have the ability of suppressing the accumulation of siRNA produced in
Agro‐infiltrationassays(Lakatosetal,2004).Therefore,p19canpreventplantdefenceagainst
transferofgenesintoplantviaA.tumefaciens.
18
2.7.2.Agro‐infiltrationinNicotianabenthamiana
Agro‐infiltration consists of injecting target genes in plants by using Agrobacterium. This was
performed by infiltrating the bacteria into the 4‐week‐old Nicotiana benthamiana leaves. After
that,plantswereallowedtogrowundergreenhouseconditionsfor1week.Agro‐infiltrationwas
achievedby fourtreatmentssuchas Agl0‐EV(emptyvector),Agl0‐PCK,Agl0‐GKand Agl0‐MLS
(leaves infiltrated with Agrobacterium Agl0 strain containing empty vector ImpactTim1.1 used
ascontrol,PCK,GKandMLSclonedgenesrespectively).TheemptyvectorusedisImpactTim1.1
whichwaspreviouslymodifiedtomakeitnon‐toxictoplant.Eachtreatmentwasreplicatedsix
times(sixplants)andineachreplicationtwoleaveswereinfiltrated.
2.7.3.Metaboliteextraction
Samplingwasdoneoneweekafterinfiltrationthenleafsampleswereputinfreezedrierfortwo
days,andafter,theywereground.ThemetaboliteswereanalysedinfoursamplessuchasAgl0‐
EV,Agl0‐PCK,Agl0‐GKandAgl0‐MLS.Theextractsfrominfiltratedleaveswereusedforanalysis
of metabolites such as glycerol, glycerol‐3‐phoshpate, glyoxylate, malate, pyruvate and
carbohydrateswhicharethemainmetabolitesdirectlycorrelatetothestudiedgenes(GK,MLS
andPCK)inlipidmobilizationpathway.However,theyareextrametabolitesalsoanalyzedsuch
as putrescine, succinate, oxalate, myo inositol, ethanolamine, 4‐trans‐caffeolyquinate, 3‐trans‐
caffeolyquinate, 3‐cis‐caffeolyquinate, GABA, glucuronate, threonate, ascorbate, citrate,
glutamate, maleate, xylitol, proline and quinate. Glycerol, glycerol‐3‐phoshpate, glyoxylate,
malate and pyruvate and most of carbohydrates were analyzed with GC‐MS using the online
derivatisation protocol while a Dionex HPLC system with an ED40‐pulsed electrochemical
detectorwasusedforstarchandsomesugars.
GC‐MSanalysis
By GC‐MS protocol, three different extraction mixes (A, B and C) were prepared. Mix A was
composedby400µLofMeOHand200µLofCHCL3.MixBwascomposedby130µLMQwater
and20µLofribitol(1mg/mL)whilemixCwascomposedby(1:1)400µLMeOHand400µLof
CHCL3.Metaboliteextractionwasperformedbymixing5mgofgroundmaterialswith175µLof
mix A followed by a brief vortex and addition of 37.5 µL of mixture B. After a new vortex, the
solutionwasputinUltrasonicbathfor10minutestogetmetabolitesoutofplanttissues.Then,
an addition of 50 µL of MQ‐water, vortex and spin for 5 minutes at 20°C at 15000rpm was
achieved. This step was followed by the transfer of 150 µL of upper (polar) phase to a 2 mL
19
Eppendorftubefollowedbyanadditionof125µLofmixC.Aftervortex,thesampleswerekept
on ice for 10 minutes and 50 µL of MQ‐water was added. Centrifugation for 5 minutes at
15000rpmat20°Cwasachievedfollowedbyanewcollectionof90%upperphaseandmixingit
withthepreviouslycollectedone.Then,20µLofpolarphasewastransferredto1.5mLglassGC‐
vialsanddryovernight.
DionexHPLCanalysis
DionexHPLCsystemwasmainlyusedforstarchquantificationandthiswasachievedfromthe
remainingpelletsafterextractingsomesugarslikesucrose,fructoseandglucose.Theremaining
pelletswerewashed4timeswith1mLofMQwater(additionof1mLMQwaterfollowedbya
centrifugationat14000rpmfor5minutesandremovalofsupernatant).Theresidualwaterwas
removedfromthepelletspriortofurtheranalyses.Inthenextstep,indrypelletsweadded50
µLof8NHCland200µLofDMSOandweputthesolutionintheshakerat60°Cfor1hourfor
homogenisationofthemixture.Afterthat,weadded150µLofMQwater,40µLof5NNaOHand
185µLofcitricacidbufferandwevortexed.
Then,thismixturewascentrifugedat14000rpmfor5minutesand100µLofsupernatantwas
transferred to new tubes. This was followed by an addition of 20 µL of AGS enzyme. Next, the
samples were put in water bath at 40°C for 1 hour. After that, 95 µL of supernatant was
transferred to Eppendorf vials in which we added 5 µL of lactose which served as internal
standardtomakeacorrectionofanyproblemthatcouldhappenduringtheprocedureandafter
avortex,thesampleswereputinAutosamplerwhichisconnectedtoDionexHPLCsystemfor
starch abundance analysis. The total number of samples was 12 (4 samples replicated three
times: empty vector, PCK, GK, MLS). In this extraction we used 10 different concentration of
starch (2, 4, 6, 8, 10, 20, 40, 60, 90, 100 µg/mL) as calibration curves for the calculation of
absolutestarchconcentrationinoursamplesandwealsoused12blanks(usedasreferenceto
set the measurement to zeroin order to prevent any errors that could happen during
measurements. The analysis of data from metabolite extraction was performed by excel and
Student t‐test to determine the difference in parameters due to treatments at 5% level of
significance.
20
3.Results
3.1.Seedgerminationandseedlingperformance
Castor seed germination percentage was significantly affected by the temperature (P = 0.022)
(Appendices).Itincreasedwithincreasingtemperature.Thus,seedincubationat20°Cledtothe
lowestgerminationpercentage(73.3%),whileincubationat25and35°Cresultedtothehighest
germination percentage (91.67 and 90.00%, respectively). Therefore, there was a significant
difference between seed germination percentage at 20 and 25°C and between 20°C and 35°C.
However, no significant difference of germination percentage between 25 and 35°C was
observed (Figure 5). From this result, both 25 and 35°C are reported to be the optimum
temperatureinrespecttogerminationpercentageincastorbean.
Figure5.Temperatureeffectoncastorseedgerminationpercentage.Seedsgerminatedat20,25and35°C.Averageand
standarddeviationarepresented.Differentlettersrepresentsignificantdifferencebetweentreatments.
TemperaturealsoaffectedR.communisseedlingestblishmentforbothoneweekafterincubation
(1WAI) and two weeks after incubation (2WAI) (P<.001) (Appendices). Percentage of normal
seedlings decreased with increasing temperature. Therefore, the lowest normal seedling
percentagewasfoundat35°C(66.7and0%for1WAIand2WAIrespectively)followedby25°C
(76.4and67.3%for1WAIand2WAIrespectively)whileseedlinggrowthat20°Cresultedinthe
21
highest percentage of normal seedlings (97.7 and 84.1% for 1WAI and 2WAI respectively)
(Figure6).
Percentage of normal seedlings decreased between 1WAI and 2WAI samples (P<.001)
(Appendices). Especially, all seedlings growth at 35°C died two weeks after incubation.
Temperature of 20°C results in healthier seedlings during early stages following the seed
germination in R. communis followed by 25°C while 35°C is the harshest temperature for
seedlingestablishment.Asdiscussedpreviously,keyenzymesinvolvedinlipidbreakdown(GK,
MLS and PCK) are necessary to provide energy required in early seedling growth and the
expression of these genes are affected by temperature. Thereby, they require optimum
temperatureformaximumactivityandthiscouldexplainwhyhightemperatureresultedinlow
seedlingperformance.
Figure6.TemperatureeffectonseedlingperformanceinR.communis.Thepercentageofnormalseedlingswascalculated
inthreedifferenttreatments(20,25and35°C)oneweekafterincubation(1WAI)(A)andtwoweeksafterincubation(B).
Averageandstandarddeviationarepresented.Differentlettersrepresentsignificantdifferencebetweentreatments.
Althoughwedidnotmeasurerootweight,itseemsthat1WAIseedlingsgrownat25and35°C
producedhigherrootmasscomparedtotheonesgrownat20°C.2WAIseedlinggrownat25°C
producedhigherrootbiomasscomparedto20and35°C(Figure7),suggestingthat25°Cisthe
besttemperatureforseedgerminationandseedlinggrowthintermsofbiomassproduction.
22
Figure7.Temperatureeffectonpost‐germinationbehaviorofcastorseedlings.Seedlingsphysiologywascheckedinthree
differenttreatments(20,25and35°C)andalsothedifferencebetweentreatmentsovertime(1WAIand2WAI:Oneand
twoweeksafterincubation).
3.2.RNAextraction
Agarose gel electrophoresis with extracted RNA showed visible RNA bands in plant materials
(roots and cotyledons) in all treatments (20, 25 and 35°C). However, higher intensity of RNA
bandswereproducedfromrootswhichweregrownat20°Ccomparedtothatofplantmaterials
whichwerecollectedfrom25°C(Figure8).
Figure8.RNAbandsinroots(R)andcotyledons(C)ofR.communisbyagarose(1%)gelelectrophoresis.Plantmaterials
werecollectedfromseedlingsoftwoweeksoldwhichweregrownat20and25°C.
23
Further RNA quality control was verified by NanoDrop spectrophotometer (Table 6).
A260/A280andA260/A230ratiosareconsideredasthemostimportantparameterstoanalyze
RNApurity(Carvalhaisetal.,2013;Chedeaetal.,2010).Theseratiosvariedbetween1.96and
2.23forrootsamplescollectedat20and25°Crespectively.AnotherparameterforRNAquality
evaluationwasRNAconcentration.Thisvariedbetween184.2and417.7ng/µLforrootsamples
collected from seedlings grown at 25 and 20°C respectively (Table 6). From absorbance ratios
andRNAconcentration,allplantmaterialscontainedpureRNAsandwereusedinfurthergene
cloning.
Table 6. RNA concentration (ng/µL) and purity (Absorbance ratios) of roots and
cotyledonssamples
Treatment
(°C)
20
25
Plant
materials
RNAconcentration
(ng/µL)
Roots
Cotyledons
Roots
Cotyledons
417.7
186.3
184.2
400.4
RNApurity(Absorbanceratio)
260/280
260/230
1.96
2.08
2.17
2.09
2.01
2.16
2.13
2.23
3.3.cDNAsynthesis,geneamplificationandpurification
3.3.1.Geneamplificationandtestofprimerperformance
Initial, gene amplification was performed by using a gradient temperature and with primers
which were specific to the target genes. In this study, we used primers for genes encoding
glycerol kinase (GK), malate synthase (MLS1 and MLS2) and phosphoenolpyruvate
carboxykinase (PCK1, PCK2 and PCK3) (Figure 9A and B). GK and MLS1 were amplified at all
temperatures except 60°C for GK and 52°C for MLS1. Moreover, MLS2 was amplified at all
temperaturesbutwithintense DNA bandsat58.5,53.9and 52°Ccomparedto60°C.PCK1and
PCK2 were amplified at all temperatures, while no amplification of PCK3 was observed. This
indicatesthatboth58.5andat53.9°CtemperaturesenableamplificationofallgenesexceptPCK
3. We decided to skip PCK3 candidate which did not show any amplification in all tested
temperatures.
24
Figure9.DNAamplificationofGK,MLS1,MLS2(1566,1704,1704bprespectively)(A)andPCK1,PCK2andPCK3(1986,
2001and1227bprespectively)(B)inR.communis.NormalPCRatgradienttemperatures(60,58.5,53.9and52°C)was
performed with specific primers. DNA used as template for amplification was the one from cotyledons at 20°C. Results
fromagarose(1%)gelelectrophoresis.
PCR was also performed with phusion polymerase and primers which contained attB sites
(Figure10AandB).TheprimerswithattBsitesenablefirsttheamplificationoftargetgenesand
latertheseattBsserveasbindingsiteswhichhelpinthecombinationofPCRproductwithattP
sites contained by donor vector during BP reaction in gene cloning to make an entry clone.
Amplificationofalltargetgeneswasobserved.
Figure 10. DNA amplification with phusion polymerase and primers with attB sites for MLS1, MLS2 (1704bp), PCK1
(1986bp)andPCK2(2001bp)(A)andGK(1566,bp)(D).Annealingtemperaturewas58.5°CforbothGKandPCK2,52°c
forbothMLS2andPCK1and60°CforMLS1.DNAusedastemplateforamplificationwastheoneincotyledonsfrom20°C.
25
3.3.2.DNAfragmentsisolationandgenepurification
Agarosegelfragmentscontainingthetargetedgeneswereusedforpurificationoftheamplified
full‐length sequence by using QIAquick kit according to the manufacturer’s instructions.
Concentrationofisolatedfragmentsrangedfrom7.3to21.5ng/µL(Table7).
Table 7. Plasmid concentration (ng/µL) of purified gene measured in NanoDrop
spectrophotometer.
Gene
GK
PCK1
PCK2
MLS1
MLS2
Concentrationofisolatedplasmid(ng/µL)
7.3
9.0
13.0
16.1
21.5
3.4.Genecloning
3.4.1.BPreactionandgenetransfertoE.colicompetentcells
In gene cloning, plasmids are also called vectors (pDONr207 in our case) and they contains a
specialregioncalledmultiplecloningsite(attPsites)whichensuresitsrecombinationwithDNA
fragment and facilitates the transfer of plasmid into host cells (E.coli) (Hartley et al, 2000).
Moreover,itcontainsageneforresistancetospecificantibiotic(gentamicininourcase)asone
selectablemarkerandalsotheCcdBgenewhichislethaltoE.colihostcellsasasecondselectable
marker (Walhout et al, 2000; Phillipe, 1996), since recombination of this vector with DNA
fragment via BP reaction inactivates this toxic gene (Phillipe, 1996). Therefore, only bacterial
cellswhichcontainedsuccessfulrecombinantDNAsgrewindifferentsinglecoloniesontheplate
withgentamicin(Figure11).
The isolated coding region sequences containing attB sites were subjected to a BP reaction
(recombination of attB sites with attP sites). This reaction is responsible to transfer these
fragments with attB sites into the donor vector pDONr207 which contained attP sites. The
recombinants were subsequently transferred into E.coli competent cells (DH5α strain) via
electroporation and grown on plate with gentamicin for selection of the transformants. The
highest number of transformed colonies was found in A (GK), B (MLS1), D (PCK1) while few
transformedcolonieswerefoundinC(MLS2)andE(PCK2).
26
Figure11.SinglecoloniesoftransformedgeneswithE.coli(DH5αstrain)competentcellsafterBPreaction.PlatesA,B,C,
DandEcontainedtransformedGK,MLS1,MLS2,PCK1andPCK2respectively.
TransformantsweregrowninLBliquidmediawithgentamicin.Then,afterharvestingthecells
bycentrifugation,plasmidswereextractedbyusingtheQIAprepSpinMiniprepKitHigh‐Yieldkit
(2.6section).PlasmidconcentrationwasmeasuredbyNanoDropandvariedfrom15.1and299.7
ng/µL(Table8).
Table8.Plasmidconcentration(ng/µL)afterBPreaction.
Gene
GK
MLS1
MLS2
PCK1
PCK2
Clone
Plasmidconcentration(ng/µL)
GK_1
GK_2
GK_3
MLS1_1
MLS1_2
MLS1_3
MLS2_1
MLS2_2
MLS2_3
PCK1_1
PCK1_2
PCK1_3
PCK2_1
PCK2_2
PCK2_3
192.0
257.1
320.9
227.0
274.4
216.3
299.7
268.2
242.3
15.1
233.8
234.2
38.3
113.4
34.8
Moreover, a normal PCR with pDONR207 primer to amplify the coding region in isolated
plasmids and agarose gel electrophoresis were performed to analyze the size of isolated
plasmids. This was done to verify if the plasmids contained the genes of interest. All isolated
plasmids except PCK2, one clone in MLS1 and two clones in PCK1 contained the target genes
whichwerereadytobeusedforsequencing(Figure12),althoughplasmidconcentrationvaried
27
between samples. Plasmid concentration varied between 192.0 to 320.9 ng/µL in GK, 216.3 to
274.4 ng/µL in MLS1, 242.3 to 299.7 ng/µL in MLS2, 15.1 to 234.2 ng/µL in PCK1 and 34.8 to
113.4ng/µLinPCK2(Table8).
Figure12.DNAbandsofIsolatedPlasmidsoffivegenes(GK,MLS1,MLS2,PCK1andPCK2)inR.communis.Threeclones
foreachgenewereused.DNAamplificationwithpDONr207primerwasperformedthroughnormalPCRandtheresults
wereshownviaagarosegelelectrophoresis.
3.4.2.GenesequencingandLRreaction
Sequencing of the isolated plasmids was performed by Macrogen Europe Company. Positive
resultswerefoundforpDONr207‐MLS1andpDONr207‐PCK1.ItwasobservedthatpDONr207‐
MLS1 and pDONr207‐PCK1 and reference genes contained the same nucleotide sequences
(1704bpand1986bprespectively).Furthermore,translationtoproteinwasalsoperformedand
aminoacidsequenceofclonedandreferencegeneswasidentical(Appendices).
Moreover, the nucleotide sequence of cloned pDONr207‐GK gene was also identical to the
referencegeneexceptforamutationinthenucleotideat1354thposition.Theplasmidisolated
fromthetransformantshasaG(Guanine),whilethereferencesequencehasaT(Thymine).In
order to check whether this mutation would affect the amino acid sequence of the translated
protein, we checked the translated amino acid sequences. No mutation in the amino acid
sequencewasfoundaftertranslationofthenucleotidesequences.
The isolated plasmids (pDONr207‐MLS, pDONr207‐GK and pDONr207‐PCK) were recombined
with expression vector (pDONr207‐pDG625) by LR clonase. Subsequently, these genes were
transferredtoE.colicompetentcellsandgrownonplatewithkanamycin.Theexpressionvector
containedagenethatmakeE.colicellsresistanttokanamycinandalsotheCcdBgenelethalto
28
thesecellsasselectablemarker.Itisalsoknownthatasuccessfulrecombinationbetweentwo
plasmids(entrycloneanddestinationvector)resultsininactivationofthisCcdBharmfulgene.
Therefore, only recombined plasmids grew on plates with kanamycin. Two clones of GK (GK_2
andGK_3),oneofMLS1(MLS1_3)andoneofPCK1(PCK1_2)wereproduced(Appendices).
Single colonies were transferred to LB liquid medium containing kanamycin and incubated at
37°C overnight. The concentration of the isolated plasmids varied from 18.9 to 111.2 ng/µL
(Table9).
Table9.Plasmidconcentration(ng/µL)ofdifferentgenesfromLRreaction.
Gene
Clone
GK
GK_2
GK_3
MLS1
MLS1_3
PCK1
PCK1_2
Sub‐clone
GK_2_1
GK_2_2
GK_2_3
GK_2_4
GK_2_5
GK_3_1
GK_3_2
GK_3_3
GK_3_4
GK_3_5
MLS1_3_1
MLS1_3_2
MLS1_3_3
PCK1_2_1
PCK1_2_2
PCK1_2_3
PCK1_2_4
PCK1_2_5
Plasmidconcentration(ng/µL)
26.5
23
27.1
26.7
31.4
44.8
21
20.3
28.2
28.3
111.2
96.2
77.9
27.6
27.5
20.6
18.9
26.6
3.4.3.PlasmiddigestionwithrestrictionenzymeandA.tumefacienscolony‐PCR.
Plasmiddigestionwithrestrictionenzymewasusedtoconfirmthepresenceoftargetgenesin
isolatedplasmidsafterLRreaction.ThedigestionofclonedgenesGK(GK_2andGK_3),MLS1_3
and PCK1_2 and empty vector (pDG625) with EcoRI restriction enzyme gives the following
restrictionfragments(Table10andAppendices).
29
Table10.Numberandsizeofplasmidfragmentsoftransformedgenesandemptyvector
withrestrictionenzyme(EcoRI).
Geneorvector
Restrictionsites
MLS1_3
2
GK_2
4
GK_3
PCK1_2
3
pDG625*
3
Sizeoffragments(bp)
12371
2952
12371
1225
1043
554
12371
2155
1083
12371
1551
1524
*Usedasemptyvectorforcontrol
Plasmid digestion and fragment production were analysed by electrophoresis in agarose gel
(1%) (Figure 13A and B). Therefore, all plasmids contained MLS1 (Figure 13A) produced two
fragmentswith2952bpand12371bp,nineoutoftenplasmidsofGKalsoproducedfourdesired
fragmentswith554,1043,1225,and12371bpwhilefouroutoffiveplasmidsofPCK1alsowere
positivewiththreedesiredfragmentsof1083,2155and 12371bp.Hence,onlyoneplasmidof
GKandPCK1didnotproducethedesiredfragments.
Figure13.RestrictionsitesofMLS1_3andpDG625anemptyvectorusedaspositivecontrol(A).DNAbandsofGK_2,GK_3,
PCK1_2 and pDG625 (B) after the digestion with EcoRI restriction enzyme. The results were shown via agarose gel
electrophoresisafteranormalPCR.
30
Withacolony‐PCR,allcoloniespresentedthetargetgenes(Figure14).
Figure14.DNAbandsofclonedGK_3_2,MLS1_3_2andPCK1_2_1aftertransformationwithAgrobacteriumtumefaciens
(Agl0 strain). Three clones from each gene were used. The results were shown via agarose gel electrophoresis after a
normalPCR.ThespecificprimerswithoutattBsiteswereused.
3.5.MetaboliteprofilingintransgenicNicotianabenthamiana
Metabolite profiling in transgenic Nicotiana benthamiana showed that significant
differenceswereonlyobservedforafewmetabolites:glucose,ethanolamine,myoinositoland
starch (Figure 15). Glucose was accumulated in leaves infiltrated with Agl0‐EV compared to
leavesinfiltratedwithAgl0‐PCK,Agl0‐GKandAgl0‐MLScells.However,nodifferenceinglucose
was observed between leaves infiltrated with Agl0‐PCK, Agl0‐GK and Agl0‐MLS cells. Higher
content of starch was found in leaves infiltrated with Agl0‐GK and Agl0‐MLS while the lower
level was observed in leaves infiltrated with Agl0‐EV and Agl0‐PCK. Ethanolamine was
accumulatedinAgl0‐EVcomparedtotheextractsfromleavesinjectedwithAgl0‐MLS.However,
no significant differences were observed between Agl0‐MLS and the leaves infiltrated neither
withbothAgl0‐PCKandAgl0‐GKnorbetweenAgl0‐PCKandAgl0‐GKandAgl0‐EV.Myoinositol
wasaccumulatedinleavesinfiltratedwithAgl0‐EVwhereasthelowestlevelofmyoinositolwas
found in leaves infiltrated with Agl0‐PCK cells. However, no difference was observed between
Agl0‐PCK and the extracts from the leaves infiltrated with Agl0‐GK and Agl0‐MLS cells.
Moreover, no difference in myo inositol was found between leaves infiltrated with Agl0‐EV,
Agl0‐GKandAgl0‐MLScells.
31
Figure15.MetaboliteprofileintransgenicleavesofNicotianabenthamiana.Agro‐infiltrationofNicotianaseedlingsof1
month old was performed with Agrobacterium tumefaciens. Metabolite extraction was achieved 1 week after leaf
infiltration through GC‐MS and Dionex HPLC protocols. Empty vector was used as control and compared with extracts
frominfiltratedleaveswithPCK,GKandMLSgenes.Errorbarswereaddedviastandarddeviationbetweentreatments.
Thedifferentlettersshowedasignificantdifferencebetweentreatmentsat5%level.
32
4.Discussion
4.1.Seedgermination
Seed germination begins with water uptake (seed imbibition) followed by enzyme activation,
initiationofembryogrowth,ruptureoftheseedcoatandradicleprotrusion(Miller,2008).Seed
germination is also associated with other important cellular events such as cell division and
elongation, respiration, RNA and protein biosynthesis (Miller, 2008; Bewley and Black, 1994).
After seed imbibition, the mRNAs which were synthesized during seed development are
translated into proteins/enzymes required for germination, storage lipid breakdown and
seedlinggrowth(Miller,2008;EastmondandGraham,2001).Properseedgerminationprovides
the necessary elements to early seedling growth and development before they become
autotrophic. At this stage, seedlings are able to synthesize their own carbohydrates through
photosynthesistoprovideenergyrequiredforgrowth(TheodoulouandEastmond,2012).
Seed germination is governed by environmental factors among which temperature and water
availability are the most important factors (Cheema et al., 2010; Mahan, 2005). Temperature
affects metabolic processes during seed germination and seedling establishment, especially
enzyme activation (Miller, 2008; Mathewson, 1998; Bewley and Black, 1994). Cardinal
temperatureisdefinedastheminimum,maximumandoptimumtemperatureinwhichplantis
abletogrowanddevelop(Shaban,2013).Atminimumtemperature,seedgerminationcanoccur
but at low percentage and slow rate, while at the optimum temperature the germination
percentageisatthehighestlevelintheshortesttime.Seedlingvigourandhealthisrelatedtothe
time that it takes between planting and seed germination or seedling emergence (Mahan and
Gitz,2007).However,maximumorhightemperatureresultstoaninhibitoryeffectonessential
proteinsrequiredfor germination andthesubsequentphysiologicalprocesses(Cheema,2011;
Shyametal,2011;Cheemaetal,2010).
Germination of castor bean seeds at different temperature (20, 25 and 35°C) was strongly
affected in terms of germination percentage. Percentage of germination increased significantly
withincreasingtemperature.Thisstudyreported20°Castemperaturewhichledtolowercastor
seed germination (variety MPA11), while both 25 and 35°C gave higher seed germination.
Cheema and colleagues (2010) reported that although seeds can germinate at 10°C, the faster
germination occurs at 25°C temperature. In another study conducted by Cheema (2011),
temperatureresponseincastorbeanvarieddependingoncultivar.Thus,thelowestandhighest
seedgerminationindex(GRI)wasfoundat10and25°CrespectivelyinBahawalpurseeds,at10
and30°CrespectivelyforTandojamseedsandat10and35°CrespectivelyforFaisalabadseeds.
33
Fromtheexperiment,thetemperatureincreaseordecreasefromtheoptimumlevelresultedin
slowgermination.Severinoandcolleagues(2012)alsoreportedthatlowtemperaturesextend
the time for germination and results in irregular seed germination. Temperature of 10°C is
considered as cold stress and in our case seeds were not submitted to cold stress but were at
leastat20°C.
4.2.Roleofstudiedgenesinseedlingperformance
CastorbeanoriginatesinEthiopiaandpreferssemi‐tropicalandtropicalconditionsforgrowth
(Miller, 2008). Generally, these regions have high temperatures and dry climates. Therefore,
Castorbeancansurviveanenvironmentwithhightemperature.However,inourcase,seedling
performancedecreasedsignificanltywiththeincreasingtemperatureuntilitledtothedeathof
allseedlingsgrownat35°Ctwoweeksafterincubation.Thiscouldbeduetothefactthathigh
temperature during germination led to down regulation of important metabolic processes for
seedlingestablishment.
It is already known that for seedling establishment, lipid breakdown is the crucial pathway to
provideenergyforseedlinggrowthinCastorbean.ItisalsoknownthatGK,MLSandPCKarethe
keyenzymesinvolvedinthispathway(Mahan,2000)(Figure16).
Figure 16. Correlation between genes encoding glycerol kinase (GK), malate synthase (MLS)and phosphoenolpyruvate
carboxykinase(PCK)andcarbohydratesbiosynthesis.G3Pmeansglycerol‐3‐phosphate.
Many studies reported the role of these enzymes in carbohydrate production and seedling
establishment.Forinstance,MahanandGitz(2007)conductedastudyinwhichtheyusedsoil
temperatureinfieldtopredicttheemergenceofcottonandthermaldependenceonvelocityof
MLS by using a enzymatically‐based mechanistic model. With this model, they found that the
rapidreactionofmalatesynthaseovertimecorrelateswiththesynthesisofcarbohydratesfrom
lipid reserves and the rate of seedling emergence in sunflower and cotton. In addition, Mahan
(2000)reportedthatMLSvelocityiscorrelatedtoglyoxyalatecycleandthisenzymeresponds
differently on temperatures according to plant species. For instance, he revealed that the
maximumvelocityincottonisreachedat35°Cwhileinsunfloweritrequires28°C.
34
In addition, Eastmond (2004) conducted a study on glycerol insensitive phenotypes in
Arabidopsisandtheyobservedthatagli1mutant(lackingGLI1,agenewhichencodesglycerol
kinase)wasnotabletobreakdownglycerolandthisledtotheaccumulationofglycerolandthe
rootgrowthinhibition.Thisinhibitoryeffectwassuppressedbyapplyingexogenoussucrosein
the medium. This indicates that a disruption of GLI activity required for glycerol catabolism
resultsinglycerolinsensitivityandpreventionofsucroseproductionforrootgrowth.
Cornahandcolleagues(2004)observedthattheexpressionofMLSishighlycorrelatedwithlipid
catabolism during post‐germination growth in Arabidopsis. This was shown by a blockage of
carbohydrate biosynthesis in an Arabidopsis mls mutant which resulted in the inhibition of
hypocotylelongation.Thisindicatesthattheglyoxylatecycleisavitalpathwayandrequiredfor
lipid breakdown in oilseed plants. Graham (2008) considered glyoxylate cycle as a central
pathwayincarbohydratessynthesisasitlinksβ‐oxidationandgluconeogenesis.Nakazawaand
colleagues (2005) ensured that glyoxylate cycle is the absolute pathway in oil catabolism
especiallyundercarbondeficiencyconditions.
Runquist and Kruger (1999) observed a strong correlation between the lipid breakdown and
expressionofMLSasitsexpressionpeakedatthestageofhigherrateoflipidcatabolism.They
concluded that effective lipid catabolism depends on MLS expression. It is known that the
expressionofthegeneencodingMLSisgovernedbytranscriptionduringseedgerminationand
post‐germinationgrowthandthattheirinductionisametabolicprocessthatensurestherapid
lipidmobilization(EttingerandHarada,1990).Inaddition,thisinductionisassociatedwiththe
oneofgenesencodingβ‐oxidationandgluconeogenesisenzymes(EastmondandGraham,2002).
Moreover,astudyconductedbyPenfieldandcolleagues(2004)inArabidopsisshowedthatnot
only a disruption of genes encoding glyoxylate cycle enzymes affect carbohydrates production
and reduction of hypocotyl elongation, but also a down‐expression of PCK1, a gene which
encodes phosphoenolpyruvate carboxykinase (PCK), prevents the gluconeogenesis for
carbohydratesynthesisindarkconditions.PCKenzymecatalysestheconversionofoxaloacetate
into phosphoenolpyruvate (Leegood and Walker, 2003; Matsuba et al., 1997). In a study they
conducted on Cucurbita pepo seedlings, they revealed that a disruption of gluconeogenesis
results to the conversion of oxaloacetate into malate, aspartate and TAC (tricarboxylic acid)
cycle (required in biosynthesis of photosynthetic tissues) instead of phosphoenolpyruvate.
Thereby,theyconcludedthatproductionofthelatermetabolitefromoxaloacetatewithPCKisa
crucialstepingluconeogenesis.
35
Briefly,GK,MLSandPCKarethekeyenzymesrequiredinglycerolcatabolism,glyoxylatecycle
and gluconeogenesis respectively for carbohydrate production required during early seedling
growth. In addition to the role of these enzymes, it was also observed that the expression of
genes that encode these enzymes is strongly affected by temperature. For instance, in an
experiment conducted in our lab on castor been seedlings, we showed that some important
metabolicenzymes(GK,MLSandPCK)weredown‐regulatedat35°Cwhencomparedto20and
25°C.Infact,expressionlevelsofgenesencodingGK,MLSandPCKenzymesdecreasedwiththe
increasing temperature. However, it was reported that a disruption of expression of these
enzymes results to low seedling establishment. Thereby, downregulation of these genes might
be the cause of low seedling performance observed at high temperature in our case (Personal
communicationPaulo,2014).
In the present study, the deleterious thermal response increased over time. Therefore,
percentageofnormalseedlingsdecreasedfrom1WAIto2WAI.Itisknownthatcastorbeanuses
lipidreserveforgerminationandthatthemobilizationofthisreserveisnecessaryforseedling
establishment before the biosynthesis of photosynthetic metabolites (Theodoulou and
Eastmond, 2012). During the first days after incubation, germination processes (water uptake,
ruptureoftheseedcoatandradicleprotrusion)andlittleenzymeactivationtakeplaceandthe
lipid mobilization which is a post‐germination process occurs after. Therefore, even lipid
mobilization can start before complete seed germination, the function of enzymes involved in
thispathwayismainlyrequiredinpost‐germinationevents(Graham,2008;BewleyandBlack,
1994).
Itwasalsoreportedthatmanygenesencodingenzymesinvolvedinlipidmobilizationarehighly
expressed2to5daysafterimbibitionandthatcompletelipidmobilizationoccursafterday5to
10afterimbibition(Eastmond,2004;Rylottetal.,2003;BewleyandBlack,1994;Huang,1992).
Leegood and Walker (2003) conducted a study on Cucurita pepo seedlings and they observed
thatgluconeogenesisreachesapeak5to8daysafterplanting.Moreover,itismentionedabove
that the expression of genes encoding GK, MLS and PCK enzymes decreased with temperature
increase. Thereby, gene expression in some days later after incubation and negative effect of
temperature on gene expression might be the causes of the increasing of deleterious thermal
responseovertime.
36
4.3.Genecloningandsequencing
We showed how genes encoding GK, MLS1 and PCK1 enzymes correlate with carbohydrate
productionandhowadownregulationofthesegenesathightemperaturecorrelateswithlow
seedling performance in castor bean. Although these genes were revealed to be important in
lipid breakdown, there was an misunderstanding on how their expression responds to
temperatureconditionsandhowthisaffectsphysiological,biochemicalandmolecularaspectsin
castor bean. Thereby, with this study we isolated and cloned coding regions of these three
candidategenesforfurtheranalyses.
In this experiment, gene sequencing (nucleotide sequence alignment) revealed that plasmids
contained GK, MLS1 and PCK1 genes were positive because their nucleotide and amino acids
sequencesmatchedthesequenceofdesiredgenes.AlthoughclonedGKcontainedonedifferent
nucleotide (G) compared to the reference gene (T), this mutation occurring during cloning
processesdidnotaffectitsaminoacidsequence.Thatiswhatsocalled’silentsinglenucleotide
polymorphism’(silentSNP).Thisoccurswhenachangeinsinglenucleotidedoesnotaffectthe
aminoacidcomposition (Komar,2007).Thismightbeexplainedbythefactthatthesubstitution
ofonebaseinDNAsequenceusuallyisconsideredassmallgeneticchangewhichdoesnothave
a discriminate effect on gene stability and function (Komar, 2007; Wang et al., 2010; Clancy,
2008). 4.4.MetaboliteprofileintransgenicNicothianabenthamiana
Briefly,manymetaboliteswereidentifiedeitherbyGC‐MSorDionexHPLCtechniques.However,
only glucose, starch, ethanolamine and myo inositol levels varied between different samples.
Glucosecontentwaslowerinleavesinfiltratedwithtargetgenes(PCK,GKandMLS).However,
starch was highly accumulated in both GK and MLS samples. This explains that glucose was
converted into starch in leaves infiltrated by these genes. The surprising result is that both
glucose and starch contents were low in sample from PCK. In this study, we used AtPCK (A.
thalianaPCK)geneasreferencetohaveRcPCK(R.communusPCK).Wehavegotthreeputative
RcPCKs(PCK1,PCK2andPCK3).However,duringcloning,onlyclonedPCK1expressedidentical
nucleotide sequence compared to reference PCK1 gene. Therefore, the mechanism behind the
lowlevelofbothglucoseandstarchinleavesinfiltratedwithPCK1couldbeduetothefactthat
amongthreePCKs,thiswasnottheexactgenethatshouldresulttopropergluconeogenesis.
37
Ethanolamine and myo inositol content was low in leaves infiltrated with target genes.
Ethanolamineisorganiccompoundwhichcontainsbothamineandalcoholchemical.Inplant,it
issynthetizedfromserineorphosphatidylserineanditisimportantforsynthesisofcholineand
membrane lipid likephosphatidylethanolamine and phosphatidylethanolamine (Kwon et al.,
2012).Unfortunately,thereisnoclearrelationshipbetweenthismetaboliteandthefunctionof
studied genes. Myo inositol is a carbohydrate classified in sugar alcohols (Gupta et al., 2010)
whichcanbesynthesizedfromglucose(SasakiandTaylor,1986).Asacarbohydrate,itmustbe
highlyaccumulatedinleavesinfiltratedbystudiedgenesespeciallybacterialcellscontainedPCK
genes.
38
Conclusion
Theaimofthepresentstudywastocloneandfunctionalcharacterizetemperatureresponsive
genes encoding glycerol kinase (GK), malate synthase (MLS) and phosphoeonylpyruvate
corboxykinase(PCK)enzymeswhich areinvolvedinlipidmobilizationin Castorbean (Ricinus
communis).
Fromthisexperimentthefollowingconclusionsaremade:
1.Castorbeangerminationandseedlingperformancearestronglyaffectedbythetemperature.
Seedgerminationpercentageincreasedwiththeincreasingtemperature.However,adecreasein
number of normal seedlings was associated with increasing temperature. Therefore, 25 and
35°C are the best temperatures for seed germination followed by 20°C. However, 20°C led to
higher seedling performance followed by 25°C, while 35°C is a harsh temperature which
resultedinlowpercentageofnormalseedlings.Inconclusion,25°Cisthebesttemperaturefor
bothgerminationandseedlingestablishmentincastorbean.
2. Seedling performance correlates with the expression and function of genes that encode GK,
MLS and PCK enzymes. The expression of these enzymes is negatively affected by the
temperature,whichmightexplainthelowseedlingsurvivalof2WAIsamplesat35°C.
3. Transient expression in N. Benthamiana leaves showed that an initial reduction in glucose
levelswas followedby anincreaseinthecontentofstarchin leavesthatwereinfiltratedwith
Agl0‐MLS and Agl0‐GK as compared to infiltration with the empty vector (Agl0‐EV). This
supports our hypothesis that these genes are required for R. communis growth at the early of
seedlingestablishment.
39
Acknowledgements
IwouldliketoexpressmysinceregratitudetomysupervisorPauloRobertoRibeirodeJesusfor
involvingmeinhisproject,hisdailyguidance,constantencouragement,constructivefeedbacks,
suggestionsandassistanceinthisresearch.Igainedatremendousamountofknowledgeunder
his supervision. I am greatly indebted to address my thanks to Wilco Ligterink for his
supervision,commentsandsuggestionsonmyreport.MyspecialthanksgotoDickVreugdenhil
and also to Henk Hilhorst for providing me the opportunity to do my thesis in the Plant
Physiologydepartment.IgreatlythanklabtechniciansespeciallyJuriaanandLeoforhelpingme
duringcloningandmetaboliteprofilingexperiments.Ialsowouldliketoexpressmythanksto
other members of the Plant Physiology department for their help, advices, encouragement,
supportandcooperationwhichmadeRadixafavourablelearningandworkingenvironmentto
me. I would like to acknowledge the moral support and encouragement of Rwandese students
duringmystayinNetherlandsandthegoodtimeIsharedwiththem.Iwouldliketosay‘thanks’
tomyhusbandfortakingcareofourchildreninmyabsence.MysincerethanksgotoNFPpeople
whose financial contribution helped me to accomplish this work. It could be unforgivable to
finish my acknowledgement without take into account the daily blessings from my Almighty
God.
40
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46
Appendices
Dailyseedgermination(20and25°C).Seedincubationwasdoneon11th‐February‐2014.
Date
Replication
Treatment(°C)
12‐Feb
13‐Feb
14‐Feb
17‐Feb
Total
Germinationrate(%)
0
0
0
0
0
0
1
0
8
13.3
10
13
13
46
76.7
9
10
12
12
43
71.7
14
13
13
14
54
90.0
10
12
12
10
44
73.3
14
14
14
13
55
91.7
1
2
3
4
20
0
0
0
25
0
0
0
20
3
4
25
10
20
25
20
25
Dailyseedgermination(35°C).Seedincubationwasdoneon17thFebruary‐2014.
Replication
Date
17‐Feb
1
2
3
4
0
0
0
0
Total
Germinationrate(%)
0
0
18‐Feb
6
3
4
2
15
25
19‐Feb
12
11
10
13
46
76.7
20‐Feb
15
15
11
11
52
86.7
21‐Feb
15
15
11
11
52
86.7
24‐Feb
15
15
12
12
54
90.0
Normalseedlingsoneweekafterseedincubation
Treatment(°C)
Replication
Total
Normalseedling(%)
10
43
97.7
11
11
42
76.4
7
8
36
66.7
Total
Normalseedling(%)
1
2
3
4
20
9
12
12
25
10
10
35
10
11
Normalseedlingstwoweeksafterseedincubation
Treatment(°C)
Replication
1
2
3
4
20
9
9
9
10
37
84.1
25
10
9
10
8
37
67.3
35
0
0
0
0
0
0
47
ANOVAtableforseedgermination(%)
Sourceofvariation
df
s.s
m.s
v.r
Fpr.
Tr
Residual
Total
2
9
11
822.22
611.11
1433.33
411.11
67.90
6.05
0.022*
*Significantdifference(P<0.05)
Meanseparationofgerminationrate(%)
Treatment(°C)
Mean
20
73.3a
25
35
91.7b
90.0b
D(LeastSignificantDifferenceofmeans(5%level)=13.18
ANOVAtableofNormalseedling(%)oneweekafterseedincubation
Sourceofvariation
df
s.s
m.s
v.r
Fpr.
Tr
Residual
2
9
2029.85
309.78
1014.93
34.42
29.49
<.001***
11
2339.63
Total
***VeryHighsignificantdifference(P<.001)
Meanseparation(%)ofNormalseedling(%)oneweekafterseedincubation
Treatment(°C)
Mean
20
25
97.7c
76.4b
35
66.7a
LSD=9.385
ANOVAtableofNormalseedling(%)twoweeksafterseedincubation
Sourceofvariation
df
s.s
m.s
v.r
Fpr.
Tr
Residual
Total
2
9
11
16073.0
526.30
16599.30
8036.50
58.48
137.43
<.001***
***VeryHighsignificantdifference(P<.001)
Meanseparation(%)ofNormalseedling(%)twoweeksafterseedincubation
Treatment(°C)
Mean
20
84.1c
25
67.3b
35
0a
LSD=12.232
48
ANOVAtableofNormalseedling(%)overtime
Sourceofvariation
df
s.s
m.s
v.r
Fpr.
Tr
2
14011.04
7005.52
150.82
<.001***
Tme
1
5173.31
5173.31
111.38
<.001***
Trt.Tme
2
4091.81
2045.91
44.05
<.001***
Residual
18
836.09
46.45
Total
23
24112.25
***VeryHighsignificantdifference(P<.001)
DNAsequencealignmentofthecodingregionofclonedGK.Highlightednucleotideinyellowshowsthedifference
inpositionbetweenclonedandreferencegenes.
ATGGCAAAACAGGAACCAGCTTTCATTGGAGCCATTGATCAAGGCACAACTAGCACCAGATTCATAATCTACAATCGCCATGCCAACTCTATTGGAT
CTCACCAGGTTGAATTCACCCAGTTCTACCCTCAAGCCGGATGGGTGGAGCATGATGCTATGGAGATACTTGAGAGCGTCAAGGTGTGTATGGCCAA
GGCAGTGGATAAAGCTACTGCTGATGGACATAATGTTGATGGTTTATTGAAGGCTATTGGGCTAACTAATCAGAGAGAGACCACTGTTATTTGGAGC
AAATCAACTGGTGTTCCTCTTTATAATGCCATTGTTTGGATGGATGTTCGTACCAGTTCTATTTGCAGGAAATTGGAGAAAGAATTACCAGGTGGAA
GGACTCATTTCATTGAGACTTGTGGTCTGCCATTAAGTACTTATTTCAGTGCAGTGAAGATACTGTGGTTGATGGAAAATGTTGATGCTGTTAAAGA
GGCTATCAAGAAAGGGGATGCTCTGTTTGGAACTATAGACTCTTGGTTAATATGGAATTTAACTGGTGGAGTGAAGGGTGGCTTGCATGTCACTGAT
GTTTCTAATGCATCTCGAACCATGCTCATGAATATCAAAACCCTTGAATGGGATAAACCTACATTGAATACTTTGGGAATTCCTGCTGAAATTCTGC
CCAAAATTATAAGCAACTCTGAGGTTATTGGAAAAATTGCAAAGGGGTGGCCAGTTACTGGCATTCCGATTGCAGGGTGTCTTGGAGACCAACATGC
TGCAATGGTAGGACAAGGATGCAAAAGAGATGAGGCCAAAAGCACTTATGGGACTGGTGCTTTCATACTTCTCAACACAGGTGATCACATAGTTCCA
TCAAAGCACGGGCTTTTAACTACTTTGGCTTATAAGCTTGGTCCAAAAGCGCCTACCAATTATGCTTTAGAGGGTTCAATTGCTATTGCTGGAGCTG
CAGTTCAATGGCTTAGAGATGGCCTTGAGCTAATTAGTAGTGCAAGTGAAATCGAGGAACTTGCCAAGCAGGTTGACTCGACTGGTGGTGTTTATTT
TGTACCTGCTTTTAATGGACTGTTTGCCCCATGGTGGCGTGATGATGCCCGTGGGGTCTGCATTGGGATCACAAGGTATACTAATAAGTCCCACATTG
CTCGAGCTGTGCTTGAGAGCATGTGTTTCCAAGTTAAAGATGTATTGGATTCAATGCACAAAGATAGAGAGGAAAAGCATAAGGACACTAAGAGGG
AGTTCCTGCTAAGAGTAGATGGTGGTGCAACTATTAACAACCTCTTGATGCAGATTCAGGCAGACTTGGTGGGACACCCAGTTGTGAGGCCAGCTGA
TATAGAAACAACAGCTCTTGGAGCAGCCTATGCTGCTGGTTTGGCTGTTGGGATTTGGACAGAGAAGGAGATTTTTGCTTCAGGAGAAAAGGCTAAG
ACAGATACCATCTTCTGTCCGAAATTAGATGAAGAACTGAGAAAGAAAAAGGTGGAATCTTGGTGCAAAGCTGTTGAAAGAACTTTTGGCTTGGCTG
ATCTTTCAATATGA
DNA sequence alignment of the coding region of GK reference. Highlighted nucleotide in yellow shows the
differenceinpositionbetweenclonedandreferencegenes.
ATGGCAAAACAGGAACCAGCTTTCATTGGAGCCATTGATCAAGGCACAACTAGCACCAGATTCATAATCTACAATCGCCATGCCAACTCTATTGGAT
CTCACCAGGTTGAATTCACCCAGTTCTACCCTCAAGCCGGATGGGTGGAGCATGATGCTATGGAGATACTTGAGAGCGTCAAGGTGTGTATGGCCAA
GGCAGTGGATAAAGCTACTGCTGATGGACATAATGTTGATGGTTTATTGAAGGCTATTGGGCTAACTAATCAGAGAGAGACCACTGTTATTTGGAGC
AAATCAACTGGTGTTCCTCTTTATAATGCCATTGTTTGGATGGATGTTCGTACCAGTTCTATTTGCAGGAAATTGGAGAAAGAATTACCAGGTGGAA
GGACTCATTTCATTGAGACTTGTGGTCTGCCATTAAGTACTTATTTCAGTGCAGTGAAGATACTGTGGTTGATGGAAAATGTTGATGCTGTTAAAGA
GGCTATCAAGAAAGGGGATGCTCTGTTTGGAACTATAGACTCTTGGTTAATATGGAATTTAACTGGTGGAGTGAAGGGTGGCTTGCATGTCACTGAT
GTTTCTAATGCATCTCGAACCATGCTCATGAATATCAAAACCCTTGAATGGGATAAACCTACATTGAATACTTTGGGAATTCCTGCTGAAATTCTGC
CCAAAATTATAAGCAACTCTGAGGTTATTGGAAAAATTGCAAAGGGGTGGCCAGTTACTGGCATTCCGATTGCAGGGTGTCTTGGAGACCAACATGC
TGCAATGGTAGGACAAGGATGCAAAAGAGATGAGGCCAAAAGCACTTATGGGACTGGTGCTTTCATACTTCTCAACACAGGTGATCACATAGTTCCA
TCAAAGCACGGGCTTTTAACTACTTTGGCTTATAAGCTTGGTCCAAAAGCGCCTACCAATTATGCTTTAGAGGGTTCAATTGCTATTGCTGGAGCTG
CAGTTCAATGGCTTAGAGATGGCCTTGAGCTAATTAGTAGTGCAAGTGAAATCGAGGAACTTGCCAAGCAGGTTGACTCGACTGGTGGTGTTTATTT
TGTACCTGCTTTTAATGGACTGTTTGCCCCATGGTGGCGTGATGATGCCCGTGGGGTCTGCATTGGGATCACAAGGTATACTAATAAGTCCCACATTG
CTCGAGCTGTGCTTGAGAGCATGTGTTTCCAAGTTAAAGATGTATTGGATTCAATGCACAAAGATAGAGAGGAAAAGCATAAGGACACTAAGAGGG
AGTTCCTGCTAAGAGTAGATGGTGGTGCAACTATTAACAACCTCTTGATGCAGATTCAGGCAGACTTGGTGGGACACCCAGTTGTGAGGCCATCTGA
49
TATAGAAACAACAGCTCTTGGAGCAGCCTATGCTGCTGGTTTGGCTGTTGGGATTTGGACAGAGAAGGAGATTTTTGCTTCAGGAGAAAAGGCTAAG
ACAGATACCATCTTCTGTCCGAAATTAGATGAAGAACTGAGAAAGAAAAAGGTGGAATCTTGGTGCAAAGCTGTTGAAAGAACTTTTGGCTTGGCTG
ATCTTTCAATATGA
AlignmentofaminoacidssequencesofclonedGK
MAKQEPAFIGAIDQGTTSTRFIIYNRHANSIGSHQVEFTQFYPQAGWVEHDAMEILESVKVCMAKAVDKATADGHNVDGLLKAIGLTNQRETTVIWSK
STGVPLYNAIVWMDVRTSSICRKLEKELPGGRTHFIETCGLPLSTYFSAVKILWLMENVDAVKEAIKKGDALFGTIDSWLIWNLTGGVKGGLHVTDVSN
ASRTMLMNIKTLEWDKPTLNTLGIPAEILPKIISNSEVIGKIAKGWPVTGIPIAGCLGDQHAAMVGQGCKRDEAKSTYGTGAFILLNTGDHIVPSKHGLL
TTLAYKLGPKAPTNYALEGSIAIAGAAVQWLRDGLELISSASEIEELAKQVDSTGGVYFVPAFNGLFAPWWRDDARGVCIGITRYTNKSHIARAVLESM
CFQVKDVLDSMHKDREEKHKDTKREFLLRVDGGATINNLLMQIQADLVGHPVVRPADIETTALGAAYAAGLAVGIWTEKEIFASGEKAKTDTIFCPKL
DEELRKKKVESWCKAVERTFGLADLSI*
AlignmentofaminoacidssequencesofGKreference
MAKQEPAFIGAIDQGTTSTRFIIYNRHANSIGSHQVEFTQFYPQAGWVEHDAMEILESVKVCMAKAVDKATADGHNVDGLLKAIGLTNQRETTVIWSK
STGVPLYNAIVWMDVRTSSICRKLEKELPGGRTHFIETCGLPLSTYFSAVKILWLMENVDAVKEAIKKGDALFGTIDSWLIWNLTGGVKGGLHVTDVSN
ASRTMLMNIKTLEWDKPTLNTLGIPAEILPKIISNSEVIGKIAKGWPVTGIPIAGCLGDQHAAMVGQGCKRDEAKSTYGTGAFILLNTGDHIVPSKHGLL
TTLAYKLGPKAPTNYALEGSIAIAGAAVQWLRDGLELISSASEIEELAKQVDSTGGVYFVPAFNGLFAPWWRDDARGVCIGITRYTNKSHIARAVLESM
CFQVKDVLDSMHKDREEKHKDTKREFLLRVDGGATINNLLMQIQADLVGHPVVRPSDIETTALGAAYAAGLAVGIWTEKEIFASGEKAKTDTIFCPKL
DEELRKKKVESWCKAVERTFGLADLSI*
DNAsequencealignmentofthecodingregionofclonedMLS1
ATGATGCGATATGATACTTATGGTGACTCTGCCCCGATCAAGAAGACGGGTGCAGGCTATGATGTTCCTGAAGGAGTGGACATTCGAGGTCGGTACG
ATGGAGAATTTGCCAAGATTCTTACAAGGGATGCCTTGCAATTCGTTGCTGACTTGCAACGGGAATTTAGAAACCGCATCAGGTATGCCATCGAGTG
TCGCAAGGAAGCCAAGAGCAGATACAATGCAGGAGCATTACCTGGGTTTGATCCTGCTACTAAATATATAAGGGAAGGAGAATGGACATGTGCTCCA
GTCCCTCCTGCTGTTGCTGATCGAAAGGTAGAGATTACAGGGCCTGTGGAGAGGAAAATGATCATCAATGCACTCAATTCAGGTGCCAAAGTTTTCA
TGGCTGACTTTGAAGATGCACTCTCACCAAGTTGGGAAAATCTGATGAGGGGACAAGTTAATTTGAGGGATGCTGTTAATGGGACTATAAGCTTCCA
TGACAAGGCCAGGAACAGGGTTTATAAGCTCAATGATCAGATAGCTAAGTTGTTTGTTCGCCCGCGCGGTTGGCATCTACCTGAGGCTCACATTTTA
ATTGATGGGGAACCTGCAACTGGTTGCCTCGTAGATTTTGGCCTATACTTTTACCATAACTATGCAGCCTTCCGTCGAAACCAAGGTGCAGGCTATGG
ACCTTTCTTCTATCTACCTAAGATGGAGCATTCAAGGGAAGCTAAGATATGGAACTGTGTGTTCGAGAAGGCGGAGAAGATGGCAGGAATAGAAAG
AGGAAGCATTAGGGCTACTGTTCTGATTGAGACACTTCCAGCTGTCTTCCAAATGAATGAAATCTTATACGAACTAAGGGATCACTCTGTTGGCTTG
AATTGTGGAAGATGGGACTATATTTTCAGCTATGTCAAGACATTCCAGGCTCATCCTGACCGCCCACTGCCAGACAGGGTTCAGGTTGGCATGACTCA
GCATTTTATGAAGAGTTACTCTGATCTCCTTGTCTGGACATGCCATAGGCGTGGTGTTCATGCCATGGGAGGGATGGCAGCTCAAATTCCAATCAGA
GATGACCCAGCGGCAAATAAGGCAGCACTGGAATTGGTGAGAAAGGACAAACTAAGAGAGGTGAAAGCAGGACATGATGGAACTTGGGCAGCACAC
CCTGGACTTATCCCAGCATGCATGGAAGTATTCGCAAACAACATGGGCAATACCCCACACCAGATTCAAGCCATGAAACGAGAAGATGCTGCGAATA
TAACAGAAGAAGATCTTATACAAAGGCCACGAGGGGTGCGCACACTCGAAGGGCTACGACTAAACACTCGAGTCGGGATTCAATACTTAGCAGCATG
GCTGACAGGAACAGGCTCAGTGCCACTGTACAACCTGATGGAAGATGCTGCAACTGCTGAGATAAGCAGAGTTCAGAACTGGCAGTGGCTCAAGTAC
GGAGTGGAATTGGATGGAGATGGGTTAGGAGTGAAAGTGACATTCGATCTGTTAGGGAGAGTGGTTGAAGACGAGATGGCTAGAATTGAAAGAGAA
GTTGGGAAAGAAAAGTTCAAGAAGGGAATGTACAAGGAAGCGTGCAAGATGTTTGTAAGGCAATGTGCTGCGCCAACTCTAGATGATTTTCTCACCT
TAGATGCCTATAATAACATTGTGATTCATTATCCAAAGGGATCATCTAGGCTGTGA
50
DNAsequencealignmentofthecodingregionofMLS1reference
ATGATGCGATATGATACTTATGGTGACTCTGCCCCGATCAAGAAGACGGGTGCAGGCTATGATGTTCCTGAAGGAGTGGACATTCGAGGTCGGTACG
ATGGAGAATTTGCCAAGATTCTTACAAGGGATGCCTTGCAATTCGTTGCTGACTTGCAACGGGAATTTAGAAACCGCATCAGGTATGCCATCGAGTG
TCGCAAGGAAGCCAAGAGCAGATACAATGCAGGAGCATTACCTGGGTTTGATCCTGCTACTAAATATATAAGGGAAGGAGAATGGACATGTGCTCCA
GTCCCTCCTGCTGTTGCTGATCGAAAGGTAGAGATTACAGGGCCTGTGGAGAGGAAAATGATCATCAATGCACTCAATTCAGGTGCCAAAGTTTTCA
TGGCTGACTTTGAAGATGCACTCTCACCAAGTTGGGAAAATCTGATGAGGGGACAAGTTAATTTGAGGGATGCTGTTAATGGGACTATAAGCTTCCA
TGACAAGGCCAGGAACAGGGTTTATAAGCTCAATGATCAGATAGCTAAGTTGTTTGTTCGCCCGCGCGGTTGGCATCTACCTGAGGCTCACATTTTA
ATTGATGGGGAACCTGCAACTGGTTGCCTCGTAGATTTTGGCCTATACTTTTACCATAACTATGCAGCCTTCCGTCGAAACCAAGGTGCAGGCTATGG
ACCTTTCTTCTATCTACCTAAGATGGAGCATTCAAGGGAAGCTAAGATATGGAACTGTGTGTTCGAGAAGGCGGAGAAGATGGCAGGAATAGAAAG
AGGAAGCATTAGGGCTACTGTTCTGATTGAGACACTTCCAGCTGTCTTCCAAATGAATGAAATCTTATACGAACTAAGGGATCACTCTGTTGGCTTG
AATTGTGGAAGATGGGACTATATTTTCAGCTATGTCAAGACATTCCAGGCTCATCCTGACCGCCCACTGCCAGACAGGGTTCAGGTTGGCATGACTCA
GCATTTTATGAAGAGTTACTCTGATCTCCTTGTCTGGACATGCCATAGGCGTGGTGTTCATGCCATGGGAGGGATGGCAGCTCAAATTCCAATCAGA
GATGACCCAGCGGCAAATAAGGCAGCACTGGAATTGGTGAGAAAGGACAAACTAAGAGAGGTGAAAGCAGGACATGATGGAACTTGGGCAGCACAC
CCTGGACTTATCCCAGCATGCATGGAAGTATTCGCAAACAACATGGGCAATACCCCACACCAGATTCAAGCCATGAAACGAGAAGATGCTGCGAATA
TAACAGAAGAAGATCTTATACAAAGGCCACGAGGGGTGCGCACACTCGAAGGGCTACGACTAAACACTCGAGTCGGGATTCAATACTTAGCAGCATG
GCTGACAGGAACAGGCTCAGTGCCACTGTACAACCTGATGGAAGATGCTGCAACTGCTGAGATAAGCAGAGTTCAGAACTGGCAGTGGCTCAAGTAC
GGAGTGGAATTGGATGGAGATGGGTTAGGAGTGAAAGTGACATTCGATCTGTTAGGGAGAGTGGTTGAAGACGAGATGGCTAGAATTGAAAGAGAA
GTTGGGAAAGAAAAGTTCAAGAAGGGAATGTACAAGGAAGCGTGCAAGATGTTTGTAAGGCAATGTGCTGCGCCAACTCTAGATGATTTTCTCACCT
TAGATGCCTATAATAACATTGTGATTCATTATCCAAAGGGATCATCTAGGCTGTGA
AlignmentofaminoacidssequencesofclonedMLS1
MMRYDTYGDSAPIKKTGAGYDVPEGVDIRGRYDGEFAKILTRDALQFVADLQREFRNRIRYAIECRKEAKSRYNAGALPGFDPATKYIREGEWTCAPV
PPAVADRKVEITGPVERKMIINALNSGAKVFMADFEDALSPSWENLMRGQVNLRDAVNGTISFHDKARNRVYKLNDQIAKLFVRPRGWHLPEAHILI
DGEPATGCLVDFGLYFYHNYAAFRRNQGAGYGPFFYLPKMEHSREAKIWNCVFEKAEKMAGIERGSIRATVLIETLPAVFQMNEILYELRDHSVGLNC
GRWDYIFSYVKTFQAHPDRPLPDRVQVGMTQHFMKSYSDLLVWTCHRRGVHAMGGMAAQIPIRDDPAANKAALELVRKDKLREVKAGHDGTWAA
HPGLIPACMEVFANNMGNTPHQIQAMKREDAANITEEDLIQRPRGVRTLEGLRLNTRVGIQYLAAWLTGTGSVPLYNLMEDAATAEISRVQNWQWL
KYGVELDGDGLGVKVTFDLLGRVVEDEMARIEREVGKEKFKKGMYKEACKMFVRQCAAPTLDDFLTLDAYNNIVIHYPKGSSRL*
AlignmentofaminoacidssequencesofMLS1reference
MMRYDTYGDSAPIKKTGAGYDVPEGVDIRGRYDGEFAKILTRDALQFVADLQREFRNRIRYAIECRKEAKSRYNAGALPGFDPATKYIREGEWTCAPV
PPAVADRKVEITGPVERKMIINALNSGAKVFMADFEDALSPSWENLMRGQVNLRDAVNGTISFHDKARNRVYKLNDQIAKLFVRPRGWHLPEAHILI
DGEPATGCLVDFGLYFYHNYAAFRRNQGAGYGPFFYLPKMEHSREAKIWNCVFEKAEKMAGIERGSIRATVLIETLPAVFQMNEILYELRDHSVGLNC
GRWDYIFSYVKTFQAHPDRPLPDRVQVGMTQHFMKSYSDLLVWTCHRRGVHAMGGMAAQIPIRDDPAANKAALELVRKDKLREVKAGHDGTWAA
HPGLIPACMEVFANNMGNTPHQIQAMKREDAANITEEDLIQRPRGVRTLEGLRLNTRVGIQYLAAWLTGTGSVPLYNLMEDAATAEISRVQNWQWL
KYGVELDGDGLGVKVTFDLLGRVVEDEMARIEREVGKEKFKKGMYKEACKMFVRQCAAPTLDDFLTLDAYNNIVIHYPKGSSRL*
DNAsequencealignmentofthecodingregionofclonedPCK1
ATGGCGGAGAATGGAGAGTTCAGCTTTAAGAGTAACAGCAGCGGACGCAACGGCCTGCCCAAGATTGTTACTCAGAAGAATGATGTTTGTCAGGATG
ACAGTGGTCCGACGGTGAAAGCTAAAACAATCGATGAACTTCACTCTCTTCAGAGGAAAAAATCAGCGCCGACCACACCCATCAAGGGGGGTGCACC
TCCTTCACCTCTCTCTGAAGAGCAACGCCAGAAACAGCAGCTCCAGTCCATCAGTGCATCTTTGGCATCATTGACACGAGAAACAGGGCCGAAGGTGG
TGAAAGGGGACCCAGCAAGGAAGGCGGAAGGGCAGACGGTGACACATGTCGAGCATCCTCCTATTTTTGCCCCAGCCATCAGTGTTAGTGATAGTTC
TCTCAAGTTTACCCACGTCCTCTACAATCTCTCTCCTGCTGAGCTGTATGAGCAAGCAATAAAGTATGAAAAGGGTTCATTTATAACATCAAATGGT
GCCTTAGCTACACTTTCTGGGGCAAAGACTGGCAGATCTCCAAGAGATAAGCGTGTCGTCAGGGACTCCACCACTGAAGGTGAACTTTGGTGGGGAA
AGGGGTCGCCTAACATTGAAATGGATGAGCATACTTTCTTGGTTAACAGGGAACGAGCTGTTGATTACTTGAACTCATTAGACAAGGTGTTCGTAAA
51
TGATCAGTTTCTGAACTGGGATCCAGAGCACCGAATTAAAGTTCGTATTGTATCTGCCAGGGCTTACCATTCATTGTTCATGCACAACATGTGTATCC
GACCCACTCCTGAAGAGCTGGAGGACTTTGGAACTCCGGACTTCACTATATACAATGCTGGGCAGTTCCCATGTAATCGTTACACCCACTACATGACT
TCTTCCACTAGCATAGACATCAATCTTGCTAGGAGAGAAATGGTCATCCTTGGCACTCAGTATGCTGGGGAAATGAAGAAAGGTCTATTCGGCGTAA
TGCATTATCTCATGCCTATGCGTCAAATTCTCTCCCTTCACTCTGGCTGCAATATGGGAAAAGATGGGGATGTTGCCCTCTTCTTTGGATTATCAGGT
ACTGGCAAGACTACTCTGTCTACTGATCACAATAGGTATTTAATCGGAGATGATGAACACTGCTGGAGTGAGAATGGTGTGTCAAACATTGAAGGTG
GTTGCTATGCTAAGTGCATCGATCTTTCAAGAGAGAAAGAGCCTGATATCTGGAATTCCATCAAGTTTGGAACTGTACTGGAGAATGTAGTGTTTGA
TGAGCATACTCGAGAAGTAGATTATTCAGACAAATCTGTCACAGAAAACACACGGGCAGCATATCCTATAGAGTACATTCCGAATGCTAAGATACCA
TGTGTTGGTCCTCATCCAAAGAATGTCATCCTTCTGGCTTGTGACGCATTCGGAGTTCTCCCACCTGTGAGCAAGCTGAGCTTGGCACAGACTATGTA
TCACTTCATCAGTGGTTATACTGCGCTGGTGGCTGGTACAGAGGATGGTATTAAGGAACCACAGGCAACATTCTCAGCTTGCTTTGGTGCAGCATTT
ATCATGCTGCATCCTACGAAATATGCAGCTATGTTGGCTGAAAAAATGCAGAAGCATGGAGCCACAGGATGGCTAGTCAATACCGGCTGGTCAGGTG
GCAGCTATGGATCAGGAAAACGTATGAAGTTGGCATACACTCGGAGAATCATTGACGCCATACATTCAGGTGACCTCTTGAGGGCAAATTACAGGAA
GACTGAAGTTTTTGGGCTTGAAATCCCAATTGAGATTGAGGGTGTGCCTTCAGAAATCCTGGACCCTGTCAACACTTGGCCGGACAAGAAAGCCTAC
AATGATACACTATTGAAGCTGGCTGGACTCTTCAGGAAAAATTTTGAGGTGTTTGCAAATTATAAGATTGGAAAAGACAACAAGCTCACCGAGGAG
ATTCTTGCAGCTGGTCCTATCTCTGATCAGATTGGTTTTTGA
DNAsequencealignmentofthecodingregionofPCK1reference
ATGGCGGAGAATGGAGAGTTCAGCTTTAAGAGTAACAGCAGCGGACGCAACGGCCTGCCCAAGATTGTTACTCAGAAGAATGATGTTTGTCAGGATG
ACAGTGGTCCGACGGTGAAAGCTAAAACAATCGATGAACTTCACTCTCTTCAGAGGAAAAAATCAGCGCCGACCACACCCATCAAGGGGGGTGCACC
TCCTTCACCTCTCTCTGAAGAGCAACGCCAGAAACAGCAGCTCCAGTCCATCAGTGCATCTTTGGCATCATTGACACGAGAAACAGGGCCGAAGGTGG
TGAAAGGGGACCCAGCAAGGAAGGCGGAAGGGCAGACGGTGACACATGTCGAGCATCCTCCTATTTTTGCCCCAGCCATCAGTGTTAGTGATAGTTC
TCTCAAGTTTACCCACGTCCTCTACAATCTCTCTCCTGCTGAGCTGTATGAGCAAGCAATAAAGTATGAAAAGGGTTCATTTATAACATCAAATGGT
GCCTTAGCTACACTTTCTGGGGCAAAGACTGGCAGATCTCCAAGAGATAAGCGTGTCGTCAGGGACTCCACCACTGAAGGTGAACTTTGGTGGGGAA
AGGGGTCGCCTAACATTGAAATGGATGAGCATACTTTCTTGGTTAACAGGGAACGAGCTGTTGATTACTTGAACTCATTAGACAAGGTGTTCGTAAA
TGATCAGTTTCTGAACTGGGATCCAGAGCACCGAATTAAAGTTCGTATTGTATCTGCCAGGGCTTACCATTCATTGTTCATGCACAACATGTGTATCC
GACCCACTCCTGAAGAGCTGGAGGACTTTGGAACTCCGGACTTCACTATATACAATGCTGGGCAGTTCCCATGTAATCGTTACACCCACTACATGACT
TCTTCCACTAGCATAGACATCAATCTTGCTAGGAGAGAAATGGTCATCCTTGGCACTCAGTATGCTGGGGAAATGAAGAAAGGTCTATTCGGCGTAA
TGCATTATCTCATGCCTATGCGTCAAATTCTCTCCCTTCACTCTGGCTGCAATATGGGAAAAGATGGGGATGTTGCCCTCTTCTTTGGATTATCAGGT
ACTGGCAAGACTACTCTGTCTACTGATCACAATAGGTATTTAATCGGAGATGATGAACACTGCTGGAGTGAGAATGGTGTGTCAAACATTGAAGGTG
GTTGCTATGCTAAGTGCATCGATCTTTCAAGAGAGAAAGAGCCTGATATCTGGAATTCCATCAAGTTTGGAACTGTACTGGAGAATGTAGTGTTTGA
TGAGCATACTCGAGAAGTAGATTATTCAGACAAATCTGTCACAGAAAACACACGGGCAGCATATCCTATAGAGTACATTCCGAATGCTAAGATACCA
TGTGTTGGTCCTCATCCAAAGAATGTCATCCTTCTGGCTTGTGACGCATTCGGAGTTCTCCCACCTGTGAGCAAGCTGAGCTTGGCACAGACTATGTA
TCACTTCATCAGTGGTTATACTGCGCTGGTGGCTGGTACAGAGGATGGTATTAAGGAACCACAGGCAACATTCTCAGCTTGCTTTGGTGCAGCATTT
ATCATGCTGCATCCTACGAAATATGCAGCTATGTTGGCTGAAAAAATGCAGAAGCATGGAGCCACAGGATGGCTAGTCAATACCGGCTGGTCAGGTG
GCAGCTATGGATCAGGAAAACGTATGAAGTTGGCATACACTCGGAGAATCATTGACGCCATACATTCAGGTGACCTCTTGAGGGCAAATTACAGGAA
GACTGAAGTTTTTGGGCTTGAAATCCCAATTGAGATTGAGGGTGTGCCTTCAGAAATCCTGGACCCTGTCAACACTTGGCCGGACAAGAAAGCCTAC
AATGATACACTATTGAAGCTGGCTGGACTCTTCAGGAAAAATTTTGAGGTGTTTGCAAATTATAAGATTGGAAAAGACAACAAGCTCACCGAGGAG
ATTCTTGCAGCTGGTCCTATCTCTGATCAGATTGGTTTTTGA
AlignmentofaminoacidssequencesofclonedPCK
MAENGEFSFKSNSSGRNGLPKIVTQKNDVCQDDSGPTVKAKTIDELHSLQRKKSAPTTPIKGGAPPSPLSEEQRQKQQLQSISASLASLTRETGPKVVKG
DPARKAEGQTVTHVEHPPIFAPAISVSDSSLKFTHVLYNLSPAELYEQAIKYEKGSFITSNGALATLSGAKTGRSPRDKRVVRDSTTEGELWWGKGSPNI
EMDEHTFLVNRERAVDYLNSLDKVFVNDQFLNWDPEHRIKVRIVSARAYHSLFMHNMCIRPTPEELEDFGTPDFTIYNAGQFPCNRYTHYMTSSTSID
INLARREMVILGTQYAGEMKKGLFGVMHYLMPMRQILSLHSGCNMGKDGDVALFFGLSGTGKTTLSTDHNRYLIGDDEHCWSENGVSNIEGGCYAKCI
DLSREKEPDIWNSIKFGTVLENVVFDEHTREVDYSDKSVTENTRAAYPIEYIPNAKIPCVGPHPKNVILLACDAFGVLPPVSKLSLAQTMYHFISGYTAL
VAGTEDGIKEPQATFSACFGAAFIMLHPTKYAAMLAEKMQKHGATGWLVNTGWSGGSYGSGKRMKLAYTRRIIDAIHSGDLLRANYRKTEVFGLEIPI
EIEGVPSEILDPVNTWPDKKAYNDTLLKLAGLFRKNFEVFANYKIGKDNKLTEEILAAGPISDQIGF*
52
AlignmentofaminoacidssequencesofPCK1reference
MAENGEFSFKSNSSGRNGLPKIVTQKNDVCQDDSGPTVKAKTIDELHSLQRKKSAPTTPIKGGAPPSPLSEEQRQKQQLQSISASLASLTRETGPKVVKG
DPARKAEGQTVTHVEHPPIFAPAISVSDSSLKFTHVLYNLSPAELYEQAIKYEKGSFITSNGALATLSGAKTGRSPRDKRVVRDSTTEGELWWGKGSPNI
EMDEHTFLVNRERAVDYLNSLDKVFVNDQFLNWDPEHRIKVRIVSARAYHSLFMHNMCIRPTPEELEDFGTPDFTIYNAGQFPCNRYTHYMTSSTSID
INLARREMVILGTQYAGEMKKGLFGVMHYLMPMRQILSLHSGCNMGKDGDVALFFGLSGTGKTTLSTDHNRYLIGDDEHCWSENGVSNIEGGCYAKCI
DLSREKEPDIWNSIKFGTVLENVVFDEHTREVDYSDKSVTENTRAAYPIEYIPNAKIPCVGPHPKNVILLACDAFGVLPPVSKLSLAQTMYHFISGYTAL
VAGTEDGIKEPQATFSACFGAAFIMLHPTKYAAMLAEKMQKHGATGWLVNTGWSGGSYGSGKRMKLAYTRRIIDAIHSGDLLRANYRKTEVFGLEIPI
EIEGVPSEILDPVNTWPDKKAYNDTLLKLAGLFRKNFEVFANYKIGKDNKLTEEILAAGPISDQIGF*
Single colonies of transformed genes with E. coli (DH5α strain) competent cells after LR reaction. Plates contained GK_2,
GK_3,MLS1_3andPCK1_2respectively(A).ColoniestransferredandgrewintoLBsolidmediumwithkanamycinforfurther
experiments(B).
NumberandsizeofrestrictionfragmentsofclonedgenesfromthedigestionwithEcoRI.
53
DNAsequencealignmentImpactTim1.1(emptyvector)
CTTAATTAATAAGCCCGATGGCTACTAAGTTTTACTATTTACCAAGACTTTTGAATATTAACCTTCTTGTAACGAGTCGGTTAAATTTGATTGTTTA
GGGTTTTGTATTATTTTTTTTTGGTCTTTTAATTCATCACTTTAATTCCCTAATTGTCTGTTCATTTCGTTGTTTGTTTCCGGATCGATAATGAAAT
GTAAGAGATATCATATATAAATAATAAATTGTCGTTTCATATTTGCAATCTTTTTTTTACAAACCTTTAATCGTTGTATGTATGACATTTTCTTCTT
GTTATATTAGGGGGAAATAATGTTAAATAAAAGTACAAAATAAACTACAGTACATCGTACTGAATAAATTACCTAGCCAAAAAGTACACCTTTCCA
TATACTTCCTACATGAAGGCATTTTCAACATTTTCAAATAAGGAATGCTACAACCGCATAATAACATCCACAAATTTTTTTATAAAATAACATGTCA
GACAGTGATTGAAAGATTTTATTATAGTTTCGTTATCTTCTTTTCTCATTAAGCGAATCACTACCTAACACGTCATTTTGTGAAATATTTTTTGAAT
GTTTTTATATAGTTGTAGCATTCCTCTTTTCAAATTAGGGTTTGTTTGAGATAGCATTTCAGCCGGTTCATACAACTTAAAAGCATACTCTAATGCT
GGAAAAAAGACTAAAAAATCTTGTAAGTTAGCGCAGAATATTGACCCAAATTATATACACACATGACCCCATATAGAGACTAATTACACTTTTAACC
ACTAATAATTATTACTGTATTATAACATCTACTAATTAAACTTGTGAGTTTTTGCTAGAATTATTATCATATATACTAAAAGGCAGGAACGCAAAC
ATTGCCCCGGTACTGTAGCAACTACGGTAGACGCATTAATTGTCTATAGTGGACGCAGCGATTAATACCCAGCTTTCTTGTACAAAGTGGGCATTAT
AAGAAAGCATTGCTTATCAATTTGTTGCAACGAACAGGTCACTATCAGTCAAAATAAAATCATTATTTGCCATCCAGCTGCAGCTCTGGCCCGTGTC
TCAAAATCTCTGATGTTACATTGCACAAGATAAAAATATATCATCATGAACAATAAAACTGTCTGCTTACATAAACAGTAATACAAGGGGTGTTAT
GAGCCATATTCAACGGGAAACGTCGAGGCCGCGATTAAATTCCAACATGGATGCTGATTTATATGGGTATAAATGGGCTCGCGATAATGTCGGGCAA
TCAGGTGCGACAATCTATCGCTTGTATGGGAAGCCCGATGCGCCAGAGTTGTTTCTGAAACATGGCAAAGGTAGCGTTGCCAATGATGTTACAGATG
AGATGGTCAGACTAAACTGGCTGACGGAATTTATGCCTCTTCCGACCATCAAGCATTTTATCCGTACTCCTGATGATGCATGGTTACTCACCACTGCG
ATCCCCGGAAAAACAGCATTCCAGGTATTAGAAGAATATCCTGATTCAGGTGAAAATATTGTTGATGCGCTGGCAGTGTTCCTGCGCCGGTTGCATT
CGATTCCTGTTTGTAATTGTCCTTTTAACAGCGATCGCGTATTTCGTCTCGCTCAGGCGCAATCACGAATGAATAACGGTTTGGTTGATGCGAGTGA
TTTTGATGACGAGCGTAATGGCTGGCCTGTTGAACAAGTCTGGAAAGAAATGCATAAACTTTTGCCATTCTCACCGGATTCAGTCGTCACTCATGGT
GATTTCTCACTTGATAACCTTATTTTTGACGAGGGGAAATTAGGCCGGGAAGCCGATCTCGGCTTGAACGAATTGTTAGGTGGCGGTACTTGGGTCG
ATATCAAAGTGCATCACTTCTTCCCGTATGCCCAACTTTGTATAGAGAGCCACTGCGGGATCGTCACCGTAATCTGCTTGCACGTAGATCACATAAGC
ACCAAGCGCGTTGGCCTCATGCTTGAGGAGATTGATGAGCGCGGTGGCAATGCCCTGCCTCCGGTGCTCGCCGGAGACTGCGAGATCATAGATATAG
ATCTCACTACGCGGCTGCTCAAACCTGGGCAGAACGTAAGCCGCGAGAGCGCCAACAACCGCTTCTTGGTCGAAGGCAGCAAGCGCGATGAATGTCTT
ACTACGGAGCAAGTTCCCGAGGTAATCGGAGTCCGGCTGATGTTGGGAGTAGGTGGCTACGTCTCCGAACTCACGACCGAAAAGATCAAGAGCAGCC
CGCATGGATTTGACTTGGTCAGGGCCGAGCCTACATGTGCGAATGATGCCCATACTTGAGCCACCTAACTTTGTTTTAGGGCGACTGCCCTGCTGCGT
AACATCGTTGCTGCTGCGTAACATCGTTGCTGCTCCATAACATCAAACATCGACCCACGGCGTAACGCGCTTGCTGCTTGGATGCCCGAGGCATAGAC
TGTACAAAAAAACAGTCATAACAAGCCATGAAAACCGCCACTGCGCCGTTACCACCGCTGCGTTCGGTCAAGGTTCTGGACCAGTTGCGTGAGCGCA
TACGCTACTTGCATTACAGTTTACGAACCAACAGGCTTATGTCAACTGGGTTCGTGCCTTCATCCGTTTCCACGGTGTGCGTCACCCGGCAACCTTGG
GCAGCAGCGAAGTCGAGGCATTTCTGTCCTGGCTGGCGAACGAGCGCAAGGTTTCGGTCTCCACGCATCGTCAGGCATTGGCGGCCTTGCTGTTCTTC
TACGGCAAGGTGCTGTGCACGGATCTGCCCTGGCTTCAGGAGATCGGAAGACCTCGGCCGTCGCGGCGCTTGCCGGTGGTGCTGACCCCGGATGAAGT
GGTTCGCATCCTCGGTTTTCTGGAAGGCGAGCATCGTTGTTCGCCCAGGACTCTAGCTATAGTTCTAGTGGTTGGCTACTAATAGGTTGTATTGATG
TTGGACGAGTCGGAATCGCAGACCGATACCAGGATCTTGCCATCCTATGGAACTGCCTCGGTGAGTTTTCTCCTTCATTACAGAAACGGCTTTTTCAA
AAATATGGTATTGATAATCCTGATATGAATAAATTGCAGTTTCATTTGATGCTCGATGAGTTTTTCTAATCAGAATTGGTTAATTGGTTGTAACACT
GGCAGAGCATTACGCTGACTTGACGGGACGGCGCAAGCTCATGACCAAAATCCCTTAACGTGAGTTTTCGTTCCACTGAGCGTCAGACCCCGTAGAA
AAGATCAAAGGATCTTCTTGAGATCCTTTTTTTCTGCGCGTAATCTGCTGCTTGCAAACAAAAAAACCACCGCTACCAGCGGTGGTTTGTTTGCCGG
ATCAAGAGCTACCAACTCTTTTTCCGAAGGTAACTGGCTTCAGCAGAGCGCAGATACCAAATACTGTCCTTCTAGTGTAGCCGTAGTTAGGCCACCAC
TTCAAGAACTCTGTAGCACCGCCTACATACCTCGCTCTGCTAATCCTGTTACCAGTGGCTGCTGCCAGTGGCGATAAGTCGTGTCTTACCGGGTTGGA
CTCAAGACGATAGTTACCGGATAAGGCGCAGCGGTCGGGCTGAACGGGGGGTTCGTGCACACAGCCCAGCTTGGAGCGAACGACCTACACCGAACTG
AGATACCTACAGCGTGAGCTATGAGAAAGCGCCACGCTTCCCGAAGGGAGAAAGGCGGACAGGTATCCGGTAAGCGGCAGGGTCGGAACAGGAGAGC
GCACGAGGGAGCTTCCAGGGGGAAACGCCTGGTATCTTTATAGTCCTGTCGGGTTTCGCCACCTCTGACTTGAGCGTCGATTTTTGTGATGCTCGTCA
GGGGGGCGGAGCCTATGGAAAAACGCCAGCAACGCGGCCTTTTTACGGTTCCTGGCCTTTTGCTGGCCTTTTGCTCACATGTTCTTTCCTGCGTTATC
CCCTGATTCTGTGGATAACCGTATTACCGCTAGCCAGGAAGAGTTTGTAGAAACGCAAAAAGGCCATCCGTCAGGATGGCCTTCTGCTTAGTTTGAT
GCCTGGCAGTTTATGGCGGGCGTCCTGCCCGCCACCCTCCGGGCCGTTGCTTCACAACGTTCAAATCCGCTCCCGGCGGATTTGTCCTACTCAGGAGA
GCGTTCACCGACAAACAACAGATAAAACGAAAGGCCCAGTCTTCCGACTGAGCCTTTCGTTTTATTTGATGCCTGGCAGTTCCCTACTCTCGCGTTAA
CGCTAGCATGGATCTCGGGCCCCAAATAATGATTTTATTTTGACTGATAGTGACCTGTTCGTTGCAACAAATTGATGAGCAATGCTTTTTTATAATG
CCAAGTTTGTACAAAAAAGCAGGCTTAGGCGCGCCAAGCTTAGACAAACACCCCTTGTTATACAAAGAATTTCGCTTTACAAAATCAAATTCGAGAA
AATAATATATGCACTAAATAAGATCATTCGGATCTAATCTAACCAATTACGATACGCTTTGGGTACACTTGATTTTTGTTTCAGTGGTTACATATAT
CTTGTTTTATATGCTATCTTTAAGGATCTGCACAAAGATTATTTGTTGATGTTCTTGATGGGGCTCAGAAGATTTGATATGATACACTCTAATCTTT
54
AGGAGATACCAGCCAGGATTATATTCAGTAAGACAATCAAATTTTACGTGTTCAAACTCGTTATCTTTTCATTCAAAGGATGAGCCAGAATCTTTAT
AGAATGATTGCAATCGAGAATATGTTCGGCCGATATGCCTTTGTTGGCTTCAATATTCTACATATCACACAAGAATCGACCGTATTGTACCCTCTTT
CCATAAAGGAAAACACAATATGCAGATGCTTTTTTCCCACATGCAGTAACATATAGGTATTCAAAAATGGCTAAAAGAAGTTGGATAACAAATTGA
CAACTATTTCCATTTCTGTTATATAAATTTCACAACACACAAAAGCCCGTAATCAAGAGTCTGCCCATGTACGAAATAACTTCTATTATTTGGTATT
GGGCCTAAGCCCAGCTCAGAGTACGTGGGGGTACCACATATAGGAAGGTAACAAAATACTGCAAGATAGCCCCATAACGTACCAGCCTCTCCTTACC
ACGAAGAGATAAGATATAAGACCCACCCTGCCACGTGTCACATCGTCATGGTGGTTAATGATAAGGGATTACATCCTTCTATGTTTGTGGACATGAT
GCATGTAATGTCATGAGCCACAAGATCCAATGGCCACAGGAACGTAAGAATGTAGATAGATTTGATTTTGTCCGTTAGATAGCAAACAACATTATA
AAAGGTGTGTATCAATAGGAACTAATTCACTCATTGGATTCATAGAAGTCCATTCCTCCTAAGTATCTAGAAACCATGGATCCAGGAGCGGCCGCAG
ATCTCCAATAAGAGCT
Transformed A. tumefaciens colonies (Agl0 strain) with cloned genes. Plates with kanamycin and rifampicin antibiotics
containedclonedgenessuchasGK,MLS1andPCK1aftertransformationviaelectroporation(A,BandCrespectively)and
aftertransfertoLBsolidmediumwiththesameantibiotics(D,EandFrespectively).
55